Management system for protected and temporarily-erased still picture information

ABSTRACT

An information storage medium used in the management system can record prescribed control information and one or more programs including video object groups each of which is constituted by one or more still pictures. A rewritable protect information for prohibiting erasure of the program is stored in the control information in unit of the program. Or, a rewritable temporary erase information for setting the video object group at a temporarily erased state is stored in the control information in a unit including the video object group.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is a continuation-in-part application of U.S. patent application Ser. No. 09/348,267, “INFORMATION STORAGE SYSTEM CAPABLE OF RECORDING AND PLAYING BACK A PLURALITY OF STILL PICTURES” filed on Jul. 7, 1999.

BACKGROUND OF THE INVENTION

The present invention relates to a management system for protection and temporal erasion of digital information containing still picture information.

The present invention more particularly relates to a system of performing setting of an erase prohibition flag (protect information) for a program comprising a set of one or more still pictures, setting of a temporary erase flag (TE) for each still picture within attribute information (S_VOB_ENT#) of the still picture, or various re-setting where an erase prohibition flag is set for a still picture within a prescribed range.

Recently, digital cameras have been prevalently used as media for digitally recording still image information. In addition to a case of digital camera, digitally-recorded still picture information is utilized as menu pictures for DVD (Digital Versatile Disc) video system in which movie information is digitally recorded and/or played back.

In a digital camera, individual sensed or photographed still pictures are stored as different files. When each still picture information is saved or stored as an independent file, the following problems occur:

a] Since still pictures are not grouped by similarity of contents or closeness of image sensing (photographing) times, it becomes troublesome to manage and search individual still pictures. In other words, it becomes troublesome to check the still picture information because it is necessary to open respective files in order to confirm the contents thereof.

b] When a plurality of pieces of still picture information are to be processed in a recordable/reproducible DVD_RTR system (DVD real time recording system), compatibility and continuity with a current DVD Video system cannot be maintained.

BRIEF SUMMARY OF THE INVENTION

The present invention has been made in consideration of the above situation, and has as its object to provide a protection/temporary-erase management system for digital information pertaining to a plurality of pieces of still picture information, while assuring, in a DVD_RTR recording/reproducing (or playing back) system which ensures certain compatibility and continuity with a current DVD Video system, consistency or continuity of a recording format and management information between moving and still pictures.

To achieve the above object, an information storage medium (1001 in FIG. 1A) used in the management system according to the present invention can record predetermined control information (RTR_VMG in FIG. 39) and one or more programs (PG#2, etc. in FIG. 41) containing one or more still pictures (B1 to B162 in FIG. 41).

The predetermined control information (RTR_VMG/PGI/PG_TY in FIG. 39) includes, in unit of a program (e.g., PG#2 in FIG. 41), (rewritable) protect information for prohibiting erase of a program.

The information storage medium (1001 in FIG. 1A) used in the management system according to the present invention can record predetermined control information (RTR_VMG in FIG. 39) and one or more programs (PG#2, etc. in FIG. 41) containing video object groups (VOG#B, VOG#E, and VOG#F in FIG. 41) each comprised of one or more still pictures (B1 to B80; B81 to B99; and B100 to B162 in FIG. 41).

The predetermined control information (RTR_VMG/S_VOGI#/S_VOB_ENT_TY in FIG. 40) includes, in units of video object groups (VOG#C and VOG#F in FIG. 41), (rewritable) temporary erase information (TE in FIG. 40) for setting a video object group to a temporarily erased state.

The information storage medium (1001 in FIG. 1A) used in the management system according to the present invention includes a first recording area (1011 in FIG. 1D) capable of recording predetermined control information (RTR_VMG) and a second recording area (1013 in FIG. 1D) capable of recording still picture data.

In the present invention, an unrecorded area (1460 in FIG. 4) can be set in at least either of the first recording area (1011 in FIG. 1D) and second recording area (1013 in FIG. 1D). The distribution of position of the unrecorded area on the information storage medium can be specified by position distribution information (1621 in FIG. 5). The position distribution information (1621 in FIG. 5) is management information (1621 in FIG. 5) pertaining to unrecorded areas (1460 in FIG. 4) within the first recording area (1011 in FIG. 1D) and second recording area (1013 in FIG. 1D).

In a protect information management method according to the present invention, rewritable protect information for prohibiting erase of a program is written in predetermined control information (RTR_VMG/PGI/PG_TY in FIG. 39) in unit of a program (e.g., PG#2 in FIG. 41).

In the protect information management method according to the present invention, rewritable temporary erase information (TE in FIG. 40) for setting a video object group to a temporarily erased state is written in the predetermined control information (RTR_VMG/S_VOGI#/S_VOB_ENT_TY in FIG. 40) in units of video object groups (VOG#C and VOG#F in FIG. 41).

In a program erase prohibition state change method according to the present invention, when a predetermined program (PG#2 in FIG. 41) containing a plurality of still pictures (B1 to B162 in FIG. 41) is in an erase prohibition state (protect information in FIG. 39 is 1b),

if the erase prohibition state of the predetermined program (PG#2) is changed (the erase prohibition range=protect range is changed from B1 to B162 to B1 to B80 in FIG. 41),

a combination of still pictures forming a video object group (VOG#B) is re-defined (step ST102, ST104, and ST108 in FIG. 42; VOG#B=B1 to B162 in FIG. 41 is re-defined as VOG#B=B1 to B80, VOG#E=B81 to B99, and VOG#F=B100 to B162), and

program numbers are newly assigned to the redefined video object groups (VOG#B, VOG#E, and VOG#F) (step ST102, ST106, and ST110 in FIG. 42; VOG#B=PG#2, VOG#E=PG#4, and VOG#F=part of PG#5).

Additional objects and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out hereinafter.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate presently preferred embodiments of the invention, and together with the general description given above and the detailed description of the preferred embodiments given below, serve to explain the principles of the invention.

FIGS. 1A to 1F are views for explaining the data structure of an information recording medium according to an embodiment of the present invention;

FIG. 2 is a view for explaining the directory structure of data files stored in a data area on the medium shown in FIGS. 1A to 1F;

FIGS. 3A to 3J are views for explaining the data structure in an AV file shown in FIG. 2;

FIG. 4 is a view for explaining an example of the sequence or arrangement (recording location) when a video object VOB of AV file data is recorded on the medium shown in FIG. 1A;

FIG. 5 is a view for explaining the data structure in an allocation map table;

FIG. 6 is a view for explaining the data structure in program chain control information (e.g., user-defined PGC information table UD_PGCIT);

FIGS. 7A and 7B are views for explaining examples of playback of video information (cell information) based on program chain PGC;

FIG. 8 is a view for explaining the data structure of management information (video title set information VTSI or management information RTR_VMGI for video real-time recording);

FIGS. 9A to 9F are views for explaining the order of sequence of video object VOBs according to video object information (M_VOBI for a moving picture or S_VOGI for a still picture);

FIGS. 10A to 10L are views for explaining the recording format of a picture object/audio object for a still picture;

FIG. 11 shows a screen display example of picture object data (still picture) played back from the medium shown in FIGS. 1A to 1F;

FIG. 12 is a view for explaining the data structure of information that pertains to a video object in a still picture AV file (S_AVFIT) shown in FIG. 8;

FIG. 13 is a view for explaining the data structure (the data structure that pertains to S_VOGI in FIG. 9F) of a video object unit VOBU in a picture object;

FIGS. 14A to 14G are views for explaining the relationship between the data structure in a VOB upon continuously recording still pictures, and the designation contents of a corresponding cell;

FIG. 15 exemplifies the data structure of cell playback information (cell information S_CI for a still picture) of a picture object, and the correspondence between the contents of cell playback information and the components shown in FIGS. 14A to 14G;

FIG. 16 is a view showing an example of another data structure of cell playback information (cell information CI) of a picture object;

FIG. 17 is a view for explaining the data structure of part_of_title (chapter) information that pertains to a still picture in AV file information (S_AVFI) for a still picture;

FIG. 18 is a view for explaining the data structure of a VOB map of the picture object shown in FIG. 17;

FIG. 19 is a block diagram showing an example of the arrangement of a digital video recording/playback apparatus (RTR video recorder) using the medium (a DVD_RTR disc capable of recording/playing back a video in real time) shown in FIGS. 1A to 1F;

FIG. 20 is a flow chart for explaining the sequence or process for recording one or more still pictures on the medium shown in FIGS. 1A to 1F;

FIG. 21 is a flow chart showing the sequence or process when one or more still pictures are played back from the medium shown in FIGS. 1A to 1F;

FIG. 22 is a flow chart showing the sequence or process when audio information is after-recorded on the medium shown in FIGS. 1A to 1F;

FIG. 23 is a view for explaining the data structure of control information/navigation data (RTR_VMG) shown in FIG. 1E or FIG. 8;

FIG. 24 is a view for explaining the contents of still picture cell information (S_CI) shown in FIG. 23;

FIG. 25 is a view for explaining the contents of still picture cell general information (S_C_GI) shown in FIG. 24;

FIG. 26 is a view for explaining the contents of each still picture cell entry point (S_C_EPI) shown in FIG. 24;

FIG. 27 is a view for explaining the contents of still picture additional audio file information (S_AAFI) shown in FIG. 12;

FIG. 28 is a view for explaining the contents of S_AAG general information (S_AAG_GI) shown in FIG. 27;

FIG. 29 is a view for explaining the contents of an additional audio entry (AA_ENT) shown in FIG. 27;

FIG. 30 is a view for explaining the contents of still picture VOB group general information (S_VOG_GI) shown in FIG. 12;

FIG. 31 is a view for explaining the first example (type 1) of the contents of a still picture VOB entry (S_VOB_ENT) shown in FIG. 12;

FIG. 32 is a view for explaining the second example (type 2) of the contents of a still picture VOB entry (S_VOB_ENT) shown in FIG. 12;

FIG. 33 is a view for explaining the third example (type 3) of the contents of a still picture VOB entry (S_VOB_ENT) shown in FIG. 12;

FIG. 34 is a view for explaining the fourth example (type 4) of the contents of a still picture VOB entry (S_VOB_ENT) shown in FIG. 12;

FIG. 35 is a view for explaining the relationship between original PGC information (ORG_PGCI shown in FIG. 8 or 23) and a still picture video file (RTR_STO.VRO shown in FIG. 2) when a still picture VOB alone is recorded;

FIG. 36 is a view for explaining the relationship between original PGC information (ORG_PGCI) and an additional audio part of a still picture (RTR_STA.VRO shown in FIG. 2);

FIG. 37 is a view for explaining the relationship among a still picture VOB, movie VOB, and original PGC information;

FIG. 38 is a view for explaining a case wherein user-defined PGC Information (FIG. 6) looks up a still picture VOB group;

FIG. 39 is a view for explaining protect information for protecting a program and the storage location of the protect information;

FIG. 40 is a view for explaining a temporary erase flag (TE) for a still picture and the storage location of the temporary erase flag;

FIG. 41 is a view for explaining a case wherein part of protected program PG#2 is re-set to an erasable state and temporarily erased state; and

FIG. 42 is a flow chart for explaining an example of the sequence or process for re-setting part of protected program PG#2 to an erasable state and temporarily erased state.

DETAILED DESCRIPTION OF THE INVENTION

Preferred embodiments of the present invention will be described hereinafter with reference to the accompanying drawings.

FIGS. 1A to 1F are views for explaining the data structure of an information recording medium according to an embodiment of the present invention.

[1] Outline of Data Structure on Information Storage Medium

A DVD_RTR disc (an optical disc utilizing phase change) 1001 as shown in FIG. 1A is known as an information storage medium that can record and play back video information or music information. In the following, the contents (data structure) of information recorded in disc 1001 will be explained.

The data structure of information recorded on the information storage medium (optical disc 1001) is roughly divided, in the order from inner side 1006 in FIG. 1B, into:

lead-in area 1002 having an embossed data zone whose light reflection surface has an embossed pattern, a mirror zone whose surface is flat (mirror surface), and a rewritable data zone capable of rewriting information;

volume & file manager information 1003 that records information which is recorded on a rewritable data zone which can be recorded/rewritten by the user, and pertains to the entire file or volume of audio & video data;

data area 1004 made up of a rewritable data zone that can be recorded/rewritten by the user; and

lead-out area 1005 made up of a rewritable data zone capable of information rewriting.

The embossed data zone of lead-in area 1002 records in advance:

information pertaining to the entire information storage medium, such as the disc type indicating a DVD-ROM, DVD-RAM, DVD-R, and so on, disc size, recording density, physical sector numbers indicating the recording start/end positions, and the like;

information pertaining to the recording/playback/erasure characteristics, such as the recording power and recording pulse width, erase power, playback power, and linear velocity upon recording and erasure; and

information pertaining to the manufacture of each information storage medium, such as the manufacturing number and the like.

The rewritable data zone of each of lead-in and lead-out areas 1002 and 1005 has:

a unique disk name recording field for each information recording medium,

a test recording field (for confirming recording/erasure conditions), and

a management information recording field that pertains to a defective field in data area 1004.

An information recording/playback apparatus can record given information on the above fields.

Data area 1004 sandwiched between lead-in and lead-out areas 1002 and 1005 can record both computer data and audio & video data, as shown in FIG. 1C.

The recording order and each recording information size of computer data and audio & video data can be arbitrarily determined. Locations where the computer data are recorded will be referred to as computer data areas 1008 and 1010, and a location where the audio & video data are recorded will be referred to as audio & video data area 1009.

As shown in FIG. 1D, the data structure of information recorded in audio & video data area 1009 contains:

anchor pointer 1015 for control information: this information is located at the leading portion of audio & video data area 1009 and indicates the start location (start address) where control information 1011 in audio & video data area 1009 is recorded;

control information 1011: this control information is required upon executing respective processes, e.g., video recording (audio recording), playback, editing, and search;

video objects 1012: this is video recording information of video data contents;

picture objects 1013: this is still picture information such as still pictures, slide pictures, and the like;

audio objects 1014: this is audio recording information of audio data contents;

thumbnail objects 1016: this is shrunk picture information such as thumbnails used upon editing or upon searching for a location a user wants to watch; and so on.

Video objects 1012, picture objects 1013, audio objects 1014, and thumbnail objects 1016 shown in FIG. 1D represent (or mean) groups of information classified in units of contents (data contents).

Hence, all pieces of video information recorded on audio & video data area 1009 are contained in video objects 1012, all pieces of still picture information are contained in picture objects 1013, all pieces of audio (voice or sound) information are contained in audio objects 1014, and all pieces of thumbnail information used in video information management and search are contained in thumbnail objects 1016.

VOB (video object) 1403 shown in FIG. 3D (to be described later) indicates a cluster (or extent) of information recorded in AV file (i.e., audio & video file) 1401, and has a definition different from that of video objects 1012 shown in FIG. 1D. Note that similar terms may have quite different meanings in different embodiments.

Furthermore, as shown in FIG. 1E, the contents of control information 1011 include:

AV data control information 1101: this is management information which manages the data structure in video object 1012 or manages information that pertains to the recording locations of optical disc 1001 serving as an information storage medium;

playback control information 1021: this is control information required upon reproduction or playback;

recording control information 1022: this is control information required upon recording (video/audio recording);

edit control information 1023: this is control information required for edition;

thumbnail control information 1024: this is management information that pertains to thumbnails (thumbnail object) used to edit or used to search for a location in video data the user wants to watch; and the like.

Note that Control information 1101 and playback control information 1021 shown in FIG. 1E correspond to RTR.IFO shown in FIG. 2, and RTR_VMG shown in FIG. 23.

As shown in FIG. 1F, the data structure in AV data control information 1101 shown in FIG. 1E is formed of:

allocation map table 1105: this is information pertaining to, for example, address setups along the actual layout on the information storage medium (optical disc 1001), and to identification of recorded/unrecorded areas;

video title set information 1106: this is time-relating information (corresponding to RTR_VMGI in FIG. 8) which indicates the overall information contents in AV file 1401 shown in FIGS. 3A-3J, and includes link information among VOBs, grouping information of VOBs for management and search, a time map table, and the like;

video object information 1107: this is information which indicates information pertaining to each VOB in AV file 1401 as shown in FIG. 3D, and which is information (corresponding to M_AVFIT/S_AVFIT in FIG. 8 or S_AVFIT in FIG. 12) pertaining to attribute (characteristic) information of each VOB and/or to each VOBU contained in the VOB;

PGC control information 1103: this is information (corresponding to PGCI in FIG. 23) that pertains to a video information playback program (sequence); and

cell playback information 1108: this is information (corresponding to CI in FIG. 23 or S_CI in FIG. 24) that pertains to the data structure of a basic unit of video information at the time of playback.

The aforementioned contents are a brief explanation of the data structure shown in FIGS. 1A to 1F. Some additional explanations of each information will be given below.

Volume & file manager information 1003 records:

information that pertains to the entire volume;

the number of files of contained PC data, and the number of files associated with AV data;

recording layer information associated with recording layer; and the like.

Especially, recorded as the recording layer information are:

the number of layers that form a disc (e.g., a single RAM/ROM two-layered disc has two layers, a single ROM two-layered disc also has two layers, and n single-sided discs are counted as n layers);

a logical sector number range table (capacity in units of layers) assigned in units of layers;

the characteristics (e.g., a DVD-RAM disc, a RAM section of a RAM/ROM two-layered disc, a CD-ROM, a CD-R, and the like) of respective layers;

an assigned logical sector number range table (including rewritable area capacity information of each area) in units of zones on a RAM area of each layer; and

unique ID information of each layer (e.g., to find out a disc exchange event in a multi-disc pack).

With the above recorded information, even for a multi-disc pack and/or RAM/ROM two-layered disc, continuous logical sector numbers can be set so as to handle such discs (or two-layered disc) as a single, large volume space.

Playback control information 1021 records:

information that pertains to a playback sequence which combines PGCs;

information (a sequence for continuously playing back all recorded cells) indicating a pseudo recording location considering the information storage medium as a single tape like a VTR or DVC in relation to the above information;

information that pertains to simultaneous playback on a plurality of screens (display areas) having different kinds of video information;

search information: this is information which records cell IDs respectively corresponding to search categories, and a table of start time in the cell, and allows the user to select and directly access the video information of interest; and the like.

Recording control information 1022 records:

program reservation recording information and the like.

Furthermore, edit control information 1023 records:

special edit information in units of PGCs (corresponding time setup information and special edit contents are described as EDL information); and

file conversion information (which converts a specific field in an AV file into a file such as an AVI file that can undergo special editing on a PC, and designates the storage location of the converted file).

Thumbnail control information 1024 describes:

management information that pertains to thumbnail objects 1016: this is designation information of the recording location of each thumbnail picture in audio & video data area 1009, designation information of a VOB or cell associated with each thumbnail picture, location information in a VOB or cell associated with each thumbnail picture, or the like (the VOB and cell will be explained later upon explaining the contents of FIGS. 3A to 3J).

[2] Directory Structure of Data Files in Data Area

The directory structure will be described below.

All pieces of information are recorded in units of files in data area 1004 in FIG. 1B, and the relationship among data files is managed by the directory structure shown in FIG. 2.

Referring to FIG. 2, a plurality of subdirectories 1451 are contained within root directory 1450 to allow easy classification in units of recorded file contents.

In the embodiment shown in FIG. 2, data files that pertain to computer data recorded on computer data areas 1008 and 1010 shown in FIG. 1C are recorded under subdirectory 1457 for computer data storage, and audio & video data recorded on audio & video data area 1009 are recorded under rewritable video title set RW_VTS (or DVD_RTAV) 1452.

On the other hand, upon copying video information recorded on a DVD Video disc or (DVD Audio disc) to the disc shown in FIG. 1A, data are copied under video title set VIDEO_TS 1455, and audio title set AUDIO_TS 1456.

Control information 1011 in FIG. 1D is recorded as a single file for recording/playback video management data. In the embodiment in FIG. 2, that information has file name RW_VIDEO_CONTROL.IFO (or real time recording information; abbreviated as RTR.IFO, or video recording manager information VR_MANGR.IFO). Furthermore, identical information is also recorded as backup information with file name RW_VIDEO_CONTROL.BUP (or VR_MANGR.BUP).

In the embodiment shown in FIG. 2, all of video objects (RTR_MOV.VRO, or VR_MOVIE.VRO) 1012, picture objects (RTR_STO.VRO, or VR_STILL.VRO) 1013, audio objects (RTR_STA.VRO, or VR_AUDIO.VRO) 1014, and thumbnail objects 1016 are recorded as single AV file 1401 (the file name in the embodiment in FIG. 2 is RW_OBJECT.OB).

Rewritable additional information 1454 (not shown in FIGS. 1A to 1F) that can be used upon recording/playing back video information can be simultaneously recorded. That information is recorded as a single file, which has file name RW_ADD.DAT (corresponding to S_AA_STI/S_AAFI in FIG. 12 or AA_ENT in FIG. 27) in the embodiment in FIG. 2.

[3] Data Structure in AV File

FIGS. 3A to 3J show an example of the data structure in an AF file. As shown in FIG. 3B, entire AV file 1401 forms a single video title set VTS (or RTR movie object RTR_MOV.VRO, or VR_MOVIE.VRO) 1402.

VTS 1402 contains a group of a plurality of VOBs (video objects) 1403, 1404, and 1405, which are separated into a plurality of part_of_titles (or a plurality of chapters) 1407 and 1408 in accordance with the contents of audio & video data and the order of information recorded in AV file 1401.

VOBs 1403, 1404, and 1405 in FIG. 3D are defined as sets of audio & video data recorded in AV file 1401, and have contents of definition being different from those of video objects 1012 shown in FIG. 1D that primarily serve the purposes of classification items of video information/still picture information/audio information/thumbnail information and the like.

Hence, VOBs 1403, 1404, and 1405 in FIG. 3D record not only information classified into video objects 1012, but also information classified into picture objects 1013, audio objects 1014, and/or thumbnail objects 1016, as shown in FIG. 1D.

Associated VOBs are grouped into a plurality of PTTs (part_of_titles or chapters or programs) 1407 and 1408 based on the information (contents) recorded in respective VOBs 1403, 1404 and 1405.

Thus, PTTs 1407 and 1408 are formed as a set of one VOB or as a set of plural VOBs.

In the embodiment shown in FIG. 3C, PTT 1408 is formed by two VOBs, i.e., VOBs 1404 and 1405, and PTT 1407 is formed by one VOB 1403 alone.

Minimum basic units of video information are called VOBUs (video object units) 1411 to 1414, and data in VOBs 1403 to 1405 are formed as sets of VOBUs 1411 to 1414, as shown in FIG. 3E.

MPEG1 or MPEG2 is prevalently used as the video information compression technique in VOBs 1403 to 1405.

According to MPEG, video information is divided into groups called GOPs with increments of about 0.5-second step, and compresses video information in units of GOPs. Video information compression units of VOBUs 1411 to 1414 are formed to have nearly the same size as that of GOP in synchronism with GOP.

These VOBUs 1411 to 1414 are recorded while being segmented into sectors 1431 to 1437 in units of 2,048 bytes. A pack structure is employed for recording of respective sectors 1431 to 1437. More specifically, raw information pieces of video, sub-picture, audio and dummy are respectively recorded in sectors 1431 to 1437 in the form of V_PCKs (video packs) 1421, 1425, 1426, and 1427, SP_PCK (sub-picture pack) 1422, A_PCK (audio pack) 1423, and DM_PCK (dummy pack) 1424.

Each dummy pack size is 2,048 bytes. However, since each pack has a 14-byte pack header at the leading portion thereof, the actual information size recorded in each pack is 2,034 bytes.

Note that DM_PCK (dummy pack) 1424 may be used for the purpose of addition of information to be additionally recorded after video recording. For instance, dummy packs are pre-inserted, and information of after recording is recorded in audio packs. Then, these audio packs are replaced (or exchanged) with the pre-inserted dummy packs. Or, information of a memo is recorded in a sub-picture pack, and this sub-picture pack is replaced (or exchanged) with the pre-inserted dummy pack.

The recording area of a DVD-RAM (DVD_RTR) disc as an example of the information storage medium (optical disc 1001) shown in FIG. 1A is segmented into a plurality of sectors wherein 2,048-byte data can be recorded per sector. In this DVD-RAM disc, recording/playback is performed in units of sectors (in units of 2,048 bytes). Therefore, when a DVD-RAM disc is used as the information storage medium (optical disc 1001), the respective packs are recorded in units of sectors 1431 to 1437, as shown in FIG. 3F.

As shown in FIGS. 3B and 3D, video title set VTS (or RTR_MOV.VRO, or VR_MOVIE.VRO) 1402 is formed by a sequence of all VOBs 1403 to 1405 in AV file 1401. By contrast, a playback sequence described in playback control information (pack control information) 1021 can designate an arbitrary range in an arbitrary VOB, and can play it back in an arbitrary playback order.

Basic video information units of playback are called cells 1441, 1442, and 1443.

Each of cells 1441, 1442, and 1443 can designate an arbitrary range in an arbitrary VOB, but cannot make designation across a plurality of VOBs (one cell cannot set a range by linking a plurality of VOBs).

In the embodiment shown in FIG. 3G, cell 1441 designates one VOBU 1412 in VOB 1403, cell 1442 designates whole VOB 1404, and cell 1443 designates the range of only a specific pack (V_PCK 1427) in VOBU 1414.

Information indicating a video information playback sequence is set by PGC (program chain) 1446, and is described by designating a single cell or by link (or chain) information of a plurality of cells. For example, in the embodiment shown in FIG. 3H, PGC (program chain) 1446 forms a playback program as a link (or a chain) of cells 1441, 1442, and 1443 (the relationship between the cell and PGC will be described in detail later).

VOBU 1403 in FIG. 3D can contain not only video information but also audio information. In this case, VOBU 1411 that forms VOB 1403 contains V_CK 1421 and SP_PCK 1422 that construct a video part, and A_PCK 1423 and DM_PCK (for after recording) 1424 that construct an audio part.

The video part is formed by a sequence header and GOP header composed of some contents on the start side of V_PCK, MPEG I-picture composed of the contents of a V_PCK group, a sequence end code composed of some contents on the end side of V_PCK, and sub-picture unit SPU composed of the contents of SP_PCK (cf. FIG. 3J).

The audio part contains audio data to be played back in synchronism with the playback of still picture using I-picture of the video part. The audio part is comprised of one or more audio frames (cf. FIG. 3I).

Note that the term “program” represents a logical unit of recorded contents which are consecutively recorded.

For instance, a program may correspond to a TV program when it is recorded via broadcasting, and may correspond to a sport event when it is recorded in Disc Camera. When a part of program is deleted, the original Program remains although the total presentation time of the Program is decreased. When a Program is modified or created as a result of content editing, the Program is defined as a logical unit which is consecutively presented.

In short, a Program is a logical unit of recorded contents, which are recognized or defined by user. A Program in the Program Set consists of one or more Original Cells. Program is defined only in the Original PGC.

[4] Contents of Allocation Map

The contents of allocation map table 105 in FIG. 1F will be described below with reference to FIG. 4.

As described above, the recording area of the DVD-RAM disc is segmented into a plurality of sectors, and logical sector numbers (LSNs) are continuously assigned in ascending order from the inner side.

A case will be considered below wherein video information is recorded in data area 1004 of the information storage medium (optical disc 1001) in the following sequence.

1. An area for recording AV file 1401 is assured in a continuous area (a<g) from logical sector numbers (LSN) a+1 to g in data area 1004 on the information storage medium (optical disc 1001).

2. Data of VOB#1 1461 is recorded in a continuous area (b<c) from logical sector numbers (LSN) b+1 to c in the area for recording AV file 1401.

3. Data of VOB#2 1462 is recorded in a continuous area (d<e) from logical sector numbers (LSN) d+1 to e in the area for recording AV file 1401.

As a result of the above processes in 1. to 3., three unrecorded areas “from a+1 to b”, “from c+1 to d”, and “from e+1 to g” in logical sector numbers (LSN) remain in AV file 1401.

When video information of VOB#3 with a large data size is recorded in these unrecorded areas, the following processes are required.

4. Data of VOB#3 is segmented or divided into a plurality of data in correspondence with the unrecorded area sizes in the area for recording AV file 1401.

5. First data 1463 of segmented VOB#3 is recorded in a continuous area (a<b) from logical sector numbers (LSN) a+1 to b.

6. Next data 1464 of segmented VOB#3 is recorded in a continuous area (c<d) from logical sector numbers (LSN) c+1 to d.

7. Last data 1465 of segmented VOB#3 is recorded in a continuous area (f<g) from logical sector numbers (LSN) f+1 to g.

As a result, unrecorded area 1460 “from e+1 to f” in logical sector numbers (LSN) remains in AV file 1401.

FIG. 4 shows the distribution of physical recorded positions of VOBs in AV file 1401 as a result of the above processes in 1. to 7.

As can be seen from the above description, when data in AV file 1401 is partially erased or when new data is additionally and repeatedly recorded in an unrecorded area in AV file 1401, single VOB data has to be segmented and recorded at a plurality of locations like data 1463, 1464, and 1465 of VOB#3.

Allocation map table 1105 shown in FIG. 1F shows information indicating the distribution of physical positions of respective data distributed and recorded in identical AV file 1401 in units of VOBs.

In the example shown in FIG. 4, unrecorded area 1460 is provided for data (e.g., data of still picture object) to be recorded in real time.

However, this unrecorded area is not dedicated for data such as a still picture object. For example, an unrecorded area like the one shown in FIG. 4 can be set for the contents of control information 1011 in FIG. 1D or for those of RTR_VMG (management information) in FIG. 1E.

In this way, an unrecorded area can be appropriately set even for control information (management information). Even if part of management information is deleted during editing or the like, the remaining management information need not be processed, to thereby simplify information management. This can greatly save the buffer memory size of a playback apparatus, which memory size is required for management information.

FIG. 5 shows the information contents of allocation map table 1105 taking the data allocation shown in FIG. 4 as an example. Allocation map table 1105 is comprised of distribution information 1621 of positions of unrecorded areas, and a plurality of pieces of distribution information 1622, 1623, and 1624 of positions of recorded data in units of VOBs.

A cluster of data units (or information pieces) having continuous logical sector numbers in each VOB will be defined as an “extent”.

In the embodiment shown in FIG. 4, data of VOB#3 are recorded as three extents. In the above example, since an area from logical sector numbers a+1 to b has continuous logical sector numbers, this area forms “extent#γ” 1473. That is, the recording positions of the data of VOB#3 are distributed to three locations, i.e., extent#γ 1473, extent#δ 1474, and extent#ε 1475.

The position distribution information that pertains to unrecorded areas or each VOB in allocation map table 1105 shown in FIG. 5 records the number 1601, 1602, 1603, or 1604 of extents at its first position. After that, first address 1606, 1607, 1608, 1609, 1610, or 1611 and size 1614, 1615, 1616, 1617, 1618, or 1619 of each extent are recorded.

Information of the subsequent extents (second extent, third extent, . . . ) may be similarly recorded.

The first address is expressed by a “differential number” (or relative sector number) from the first logical sector number of AV file 1401. When each first address is expressed by a differential number, if the entire contents of AF file 1401 are transplanted to another information recording medium, information in allocation map table 1105 need not be changed, thus improving file portability.

In FIG. 5, the extent size is expressed by the number of sectors. The extent size may be expressed by the last address of each extent in place of the number of sectors.

In the DVD-RAM disc (DVD_RTR disc) format, information indicating a physical address on the information storage medium (optical disc 1001) is called a physical sector number (PSN), the entire address used by the file system is called a logical sector number (LSN), and an address defined on the file system in data area 1004 in FIG. 1A is called a logical block number (LBN), thus distinguishing PSN, LSN, and LBN from each other.

However, if this convention is always observed, the description becomes complicated. For this reason, in FIGS. 4 and 5, an expression based on logical sector numbers (LSN) is used for the sake of easy understanding.

Note that the information storage medium (1001 in FIG. 1A) used in the management system according to the present invention can include a first recording area (1011 in FIG. 1D) for recording predetermined control information (RTR_VMG) and a second recording area (1013 in FIG. 1D) for recording still picture data. An unrecorded area (1460 in FIG. 4) can be set in at least either of the first recording area (1011 in FIG. 1D) and second recording area (1013 in FIG. 1D) (i.e., the first and/or second recording area). The position distribution of the unrecorded area on the information storage medium can be specified by position distribution information (1621 in FIG. 5).

[5] Contents of Playback Control Information 1021

The contents of playback control information 1021 will be described below with reference to FIGS. 6 and 7A, 7B. PGC (program chain) control information 1103 in playback control information 1021 has the data structure shown in FIG. 6, and the playback order is determined by PGC and cells. PGC is a unit that designates the playback order of cells and executes a given playback sequence. On the other hand, each cell indicates a playback period (or interval) that designates playback data in each VOB by the start and end addresses, as shown in FIGS. 3D to 3G.

PGC control information 1103 is composed of PGC information management information 1052, one or more search pointers 1053 and 1054 of PGC information, and a plurality of pieces of PGC Information 1055, 1056, and 1057.

PGC information management information 1052 contains information (number of PGC information) indicating the number of PGCs. Each of search pointers 1053 and 1054 of PGC Information points to the first position of each PGC information, and allows an easy search.

Each PGC information 1055, 1056, or 1057 includes PGC general information 1061, one or more pieces of program information (PGI#m), one or more cell IDs (or CI_SRP#m), and one or more pieces of cell information (CI#m).

PGC general information (PGC_GI) 1061 contains information (number of cell playback information) indicating the playback time of PGC and the number of cells.

Or, PGC_GI 1061 may contain information indicating the number of programs (PGs) and the number of search pointers (CI_SRP) of cell information.

As shown in FIGS. 7A and 7B, playback data are designated as a playback period in units of cells from cell-A to cell-F, and PGC information is defined in each PGC.

1. PGC#1 exemplifies a case wherein it is composed of cells that designate a continuous playback period, and its playback order is cell-A→cell-B→cell-C.

2. PGC#2 exemplifies a case wherein it is composed of cells that designate an intermittent playback period, and its playback order is cell-D→cell-E→cell-F.

3. PGC#3 exemplifies a case wherein playback can be done intermittently irrespective of the direction of playback or repetitive playback, and its playback order is cell-E→cell-A→cell-D→cell-B→cell-E.

Control information (RTR.IFO) 1011 shown in FIG. 1D or 2 contains navigation data RTR_VMG (real time recording video manager) corresponding to control information 1101 and control information 1021, as shown in FIG. 1E. This RTR_VMG contains video title set information VTSI (or information RTR_VMGI of RTR_VMG) 1106, as shown in FIG. 1F.

This information (RTR_VMGI) 1106 contains information used upon playing back a sequence of VOBs 1403, 1404, 1405, . . . , shown in FIG. 3D.

The data structure and contents of RTR_VMG in FIG. 1E (or RTR.IFO in FIG. 2) will be explained below with reference to FIG. 8.

As shown in FIG. 8, navigation data RTR_VMG (control information RTR.IFO) is comprised of RTR video manager information (RTR_VMGI), a movie AV file information table (M_AVFIT), a still picture AV file information table (S_AVFIT), original PGC information (ORG_PGCI), a user-defined PGC information table (UD_PGCIT), a text data manager (TXTDT_MG), and a table (MNFIT) of information that pertains to the manufacturer.

RTR_VMGI contained in this RTR_VMG corresponds to video title set (VTS) information 1106 shown in FIG. 1F.

This information (RTR_VMGI) 1106 contains VTS general information 1751, VOB sequence information 1752, PTT information 1753, and VTS time map table 1754, as shown in FIG. 8.

Put otherwise, this information (RTR_VMGI) 1106 contains a play list search pointer table (PL_SRPT) corresponding to VOB sequence information 1752, and a video manager information management table (VMGI_MAT) corresponding to VTS general information 1751.

Table PL_SRPT contains information 1756 indicating the number of VOBs in VTS (or the number of play list search pointers and the end address of PL_SRPT), information 1757 indicating the ID of the first VOB in a VOB sequence (or first play list search pointer PL_SRP#1), information 1758 indicating the ID of the second VOB in the VOB sequence (or second play list search pointer PL_SRP#2), and the like.

Each play list search pointer (PL_SRP) contains information (PL_TY) indicating the type of a play list, PGC number information (PGCN) corresponding to this play list, information (PL_CREATE_TM) indicating the date of creation of this play list, information (PRM_TXTI) of primary text associated with this play list, number information (IT_TXTI_SRPN) of a search pointer of item text used in this play list, and thumbnail pointer information (THM_PTRI) indicating a thumbnail picture corresponding to the recording contents of this play list.

The table (PL_SRPT) that contains these pieces of information 1756, 1757, 1758, . . . corresponds to VOB sequence information 1752 contained in VTSI (RTR_VMGI) 1106.

The contents of VTSI (RTR_VMGI) 1106 can be summarized as follows.

[6] Contents of Video Title Set Information (VTSI or RTR_VMGI) 1106

That is, as shown in FIG. 8, the data structure in video title set information (or RTR_VMGI) 1106 records:

video title set general information 1751 . . . . This information pertains to general contents of a video title set (or RTR data in AV file 1401 in FIG. 2);

video object sequence information 1752 . . . . In the data structure shown in FIGS. 3A to 3J, serial numbers are set for all VOBs in video title set 1402 (=AV file 1401). This information describes serial number information of VOBs according to this sequence;

part of titles information 1753 . . . . Object data recorded in AV file 1401 are grouped in units of associated data for the purpose of each data management and search, and video title names are set in units of groups. The group (part_of_title) is formed of a set of VOBs. This information describes VOB information contained in each part_of_title; and

video title set time map table 1754 . . . . This information pertains to VOBU position information at specific time intervals according to the video object sequence in relation to VOBs which are classified into video objects 1012 and audio objects 1014 in video title set 1402.

The detailed data structure in video object sequence information 1752 is shown on the right side in FIG. 8. That is, the total number 1756 of VOBs (or PL_SRPTI) contained in the video title set is recorded at the first position. After that, VOB_IDs (or PL_SRP#1, PL_SRP#2, . . . , PL_SRP#n) 1757, 1758, . . . corresponding to serial numbers are recorded in the sequence (video object sequence) order.

The sequence indicated by video object sequence information 1752 can be arbitrarily set by the user or information recording/playback apparatus side in, e.g., “the recording order to AV file 1401 (ascending order of recording time)”, “the recording allocation order on the information storage medium (optical disc) shown in FIG. 4”, “the VOB size order”, and the like.

By sequentially determining the order of all VOBs in VTS (video title set) 1402, a user interface similar to a VTR that records video data on a single table can be provided.

For example, the following processes can be done using video object sequence information 1752:

to search for a scene the user wants to watch by fast-forwarding (FF) or rewinding (FR) a tape;

to confirm the entire recording contents by fast-forwarding (FF) the tape; and

to search for an unnecessary recorded scene by fast-forwarding (FF) or rewinding (FR) the tape, and to overwrite new video information on that scene.

The information contents of video object sequence information 1752 shown on the right side in FIG. 8 will be explained below with reference to FIGS. 9A to 9F.

A case will be examined first wherein VOB#1 to VOB#3 are recorded to have the allocation order on the information storage medium (optical disc) shown in FIG. 4, and this recording is done in the order of 1. to 7. described in “description of allocation map table contents”.

FIG. 9C shows the sequence order which is set for these data in “the recording order to AV file 1401 (ascending order of recording time)”. Compared to FIG. 4, the allocation order from extent#α 1471 to extent#Ε 1470 has changed.

“First VOB_ID 1757 in the video object sequence” shown in FIG. 8 designates “VOB#1 1461” in FIG. 9C, and “second VOB_ID 1758 in the video object sequence” designates “VOB#2 1462” in FIG. 9C.

FIG. 9F shows another embodiment designated by video object sequence information 1752.

VOB#A 1771 and VOB#B 1772 belong to (are classified to) video objects (movie VOB information M_VOBI#) 1012, VOB#C 1773, VOB#F 1776, and VOB#G 1777 to audio objects 1014, and VOB#D 1774 and VOB#G 1777 to picture objects (still picture VOB group information S_VOGI#) 1013.

In this way, the sequence order can be designated independently of the VOB types. In FIG. 9F, VOBs (VOB#H 1778 and VOB#I 1779) that belong to thumbnail objects 1016 are set at the end of the sequence.

[7] Recording Format of Still Picture Information (or Picture Object)

The recording format upon recording still picture information on the information storage medium (optical disc 1001) shown in FIG. 1A will be explained below.

Still picture information or audio information (information that additionally records audio data of a comment for each still picture information by after recording) to be added later to still picture information are recorded at a location of picture objects 1013 or audio objects 1016 in FIG. 1D.

The format of recording the still picture information is designed to be capable of continuously recording a plurality of still pictures assuming that a plurality of still pictures sensed by a digital camera are recorded on the information storage medium (optical disc 1001) at one time. In order to allow to continuously record a plurality of still pictures, the format is designed to record at least two still pictures at neighboring locations on the information storage medium (optical disc 1001).

A still picture or audio information to be added to the still picture follows the data structure shown in FIGS. 3A to 3J to attain format continuity and matching with video information (video objects 1012).

In MPEG1 or MPEG2 as one type of recording format (video information compression format) of video information, compressed information for one corresponding video frame is present at the start position of the aforementioned GOP in the form of “I-picture”.

As shown in FIGS. 10C and 10I, input still pictures are converted into I-pictures 1706, 1707, 1708, and 1709 using the MPEG1 or MPEG2 compression technique, and these I-pictures are recorded on the information storage medium (optical disc 1001) while being stored in V_PCKs (video packs) 1661, 1662, 1663, 1668, 1669, 1670, 1671, 1672, 1673, and 1674.

As described above, on the DVD-RAM (DVD_RTR) disc, each V_PCK (video pack) is recorded in units of sectors each having a recording size of 2,034 bytes (see FIG. 3F) [one sector size is 2,048 bytes, but since each pack has a 14-byte pack header, the recording size per pack is 2,034 bytes].

When the I-picture size corresponding to one still picture information is smaller than an integer multiple of 2,034 bytes, dummy information 1704 is recorded in that short field. In this way, each I-picture can just fall within an integral number of sectors.

Since I-picture size 1808 in each VOBU is recorded in information of a VOBU map for picture objects, as shown in FIG. 13 (to be described in detail later), the start position of dummy information 1704 in V_PCK (video pack) 1670 can be determined. Hence, the contents of dummy information 1704 can be arbitrarily set.

As the contents of dummy information 1704, for example, a sequence end code (or a packet header with stream ID=0xbe) can be recorded as specific information which can be specified as dummy when it is played back, in addition to padding data with all “0”s or all “1”s.

Note that allocation of I-pictures is omitted in FIGS. 10F and 10L, but the data has the same structure as in FIGS. 10C and 10I.

For example, when a still picture is sensed using a digital camera, and some comment is to be directly added by handwriting on that sensed picture (still picture), the information of the comment contents can be recorded as a sub-picture stream in SP_PCKs (sub-picture packs) 1681, 1682, 1983, and 1684 in addition to the still picture recorded as I-picture in V_PCK.

Upon playback, I-picture still picture information in V_PCK and sub-picture information in SP_PCKs are displayed to overlap each other.

Audio information that stores a comment for each still picture as audio data is recorded in A_PCKs (audio packs) 1691 to 1702.

In this manner, V_PCKs 1661 to 1674, SP_PCKs 1681 to 1684, and A_PCKs 1691 to 1702 are gathered in units of associated still pictures, and are grouped in units of VOBUs (video objects for picture objects) 1641 to 1650. Hence, in the format shown in FIGS. 10A to 10L, each still picture forms individual (different) VOBU.

In the embodiment shown in FIGS. 10A to 10L, V_PCKs and SP_PCK are recorded before A_PCKs in each VOBU. As a result, the individual packs are separated in each VOBU, and information in each pack can be easily managed.

However, the embodiment of the present invention is not limited to the aforementioned limitation, and allows to allocate A_PCKs, V_PCKs, and SP_PCKs in an arbitrary order as in the recording format in video objects 1012.

Furthermore, V_PCKs 1664 having still picture information recorded in the I-picture format must be allocated in single VOBU 1642, but A_PCK (1694) that records part of audio information associated with VOBU 1642 can be allocated in next VOBU 1643.

This is because, as will be described later with reference to FIG. 13, continuous audio information can be separated in correspondence with each still image, using information of E_PTM (presentation terminating time) 1814 of audio information recorded in VOBU map 1738 for picture objects.

As the format that can continuously record a plurality of pieces of still picture information, the format structure shown in FIGS. 10A to 10L permits the following two different methods and mixed recording by both the methods.

1) One VOB is formed of a plurality of VOBUs.

2) One VOB has only one VOBU, and VOBs each of which records a single still picture are grouped to construct video title VTT.

FIGS. 10D to 10L show the former format structure 1), and FIGS. 10A to 10C show the latter format structure 2).

In the former format structure 1), FIGS. 10D to 10F show the basic structure. As special examples, FIGS. 10G to 10I show a structure which does not include any audio information (A_PCK), and FIGS. 10J to 10L show a structure which does not include any original still picture (V_PCK).

After a plurality of pieces of still picture information which do not contain any audio information and are sensed by a digital camera are recorded on the information storage medium (optical disc 1001) at one time, the user may often input memo data (additionally recorded as SP_PCK) or audio data (additionally recorded as A_PCK) for each still picture while observing the plurality of pieces of recorded still picture information.

In such case, efficient editing and recording can be done when only additional data (memo and audio data) are gathered to form and record a VOB different from that which records original still picture information, on the information storage medium (optical disc 1001). This is because, when additional data are recorded as another VOB, the contents of a VOB that records original still picture information need not be changed.

In this fashion, the recording format in VOB 1634 that gathers only additional data (memo and audio data) for the purpose of easy editing for still picture information has a structure (which contains only A_PCK and SP_PCK without any V_PCK) similar to that shown in FIGS. 10J to 10L.

Note that I-picture data shown in FIGS. 10C and 10I corresponds to that shown in FIG. 3J, and dummy data shown in FIGS. 10C and 10I corresponds to dummy pack DM_PCK shown in FIG. 3F.

Also, video pack V_PCK, sub-picture pack SP_PCK, and audio pack A_PCK shown in FIGS. 10A to 10L respectively correspond to V_PCK, SP_PCK, and A_PCK shown in FIG. 3F.

Dummy pack DM_PCK shown in FIG. 3F or FIGS. 10C and 10I can be appropriately used for the purpose of audio data after recording and the like. For example, when the size of an encoded I-picture data cluster (extent) does not match an integer multiple of the block size (16 sectors/32 kbytes) of an error correction code (ECC) that uses a product code, DM_PCK can be added to this data cluster as needed, so that the I-picture data cluster size matches an integer multiple of 32 kbytes.

When the cluster (extent) sizes of all I-picture data that form still pictures are matched with an ECC block unit (an integer multiple of 32 kbytes) by adding DM_PCK, the following merits are obtained.

For example, when one of a plurality of still pictures that have been continuously recorded on the medium shown in FIG. 1 is replaced by another still picture (or erased), since the still picture (I-picture) to be replaced (or erased) has an ECC block unit even if it has a size different from the original still picture, the ECC block units of I-pictures which are not replaced (not erased) are not disturbed.

For this reason, even when one of still pictures is replaced by another still picture (or erased), ECC coding of I-pictures which are not replaced (not erased) need not be redone. Since ECC coding need not be redone, the operation speed of an RTR recorder can be improved accordingly, and recorded still pictures can be smoothly edited (to replace or erase some still pictures).

However, when the size of a still picture to be replaced is larger than the original still picture size, the still picture data to be replaced is partially recorded at another recording location. That is, the replaced still picture gets fragmented. When the seek speed of a disc drive that reads out data from the medium shown in FIG. 1 is low, playback of the fragmented still picture requires a relatively long period of time. Hence, when an RTR recorder having no high-speed drive is used in playing back still pictures, the recorded data are preferably arranged (to be re-recorded to remove fragmentation) as needed.

When the latter format 2) shown in FIGS. 10A to 10C is adopted as the format that allows to continuously record a plurality of pieces of still picture information, a plurality of VOBs are grouped, as shown in FIG. 3C, to belong to different groups of VTTs (video titles) 1407 and 1408.

The recording format shown in FIGS. 10A to 10L can record at least two still pictures at neighboring locations on the information storage medium (optical disc 1001), and can continuously record a plurality of still pictures in general. For this reason, for example, when a plurality of still pictures sensed by a digital camera are recorded on the information storage medium (optical disc 1001) at one time, a practical effect and feature can be obtained, i.e., quick recording can be attained.

In addition, the recording format that can record a plurality of still pictures in a VOB has the following practical effects.

In the conventional recording format for a plurality of still pictures sensed by a digital camera, still pictures are divisionally recorded one by one in different data files. When still pictures are divisionally recorded in different files, neither image sensing order information among still pictures nor grouping information among still pictures are available. By contrast, a negative film (or a positive film prepared as needed) is available in case of a photographic film. For this reason, when a specific still picture is to be designated upon making an additional print, a still picture to be printed can be found by a search on the negative film in the photographing order.

In an information recording/playback apparatus (video recorder) for recording video information shown in FIG. 19, information of video object 1632 for picture objects recorded on the information storage medium (optical disc 1001) is read, and still pictures can be displayed on the screen in the allocation order of VOBUs 1642 to 1644 like a positive film shown in FIG. 11.

For example, a still picture at the left end in FIG. 11 expresses information of VOBU 1642, and the central still picture expresses information of VOBU 1643. The still pictures shown in FIG. 11 can be moved to the right or left on the screen, and the user designates a still picture to be edited (or to be hard-copied). Unlike video objects 1012, still picture information designates an individual still picture using the display shown in FIG. 11. (In video objects 1012, the video information range to be edited is designated by the display or presentation time.)

[8] Data Structure in Video Object Information with respect to Still Picture Information

The data structure in video object information that pertains to still picture information will be explained below.

Video object information (or AVFIT) shown in FIG. 1F is divided into a management information field (M_AVFIT in FIG. 8) that pertains to general video information, and a management information field (S_AVFIT in FIG. 8) that pertains to still picture information. FIG. 12 shows the data structure in the latter management information field (S_AVFIT) that pertains to still picture information.

The still picture AV file information table (S_AVFIT) contained in navigation data RTR_VMG shown in FIG. 8 contains still picture AV file information table information (S_AVFITI), still picture VOB stream information (S_VOB_STI#1 to S_VOB_STI#n), still picture AV file information (S_AVFI), still picture additional audio stream information (S_AA_STI#1 to S_AA_STI#m), and still picture additional audio file information (S_AAFI), as shown in the left column in FIG. 12.

The still picture AV file information (S_AVFI) contains VOB information (or S_AVFI general information S_AVFI_GI) 1721 for picture objects management information, search pointer #1 (or still VOB group information search pointer S_VOGI_SRP#1) 1726 of VOB information for picture objects, . . . , #i (S_VOGI_SRP#i) 1727, . . . , #k (S_VOGI_SRP#k) 1728, and VOB information #1 (or still picture VOB group information S_VOGI#1) 1731 for picture objects, . . . , #i (S_VOGI#i) 1732, . . . , #k (S_VOGI#k) 1733, as shown in the central column in FIG. 12.

VOB information #i for picture objects (or still picture VOB group information S_VOGI#i) has the contents shown in the right column in FIG. 12 (the same applies to VOB information #1 and information #k for picture objects).

That is, VOB information #i for picture objects is comprised of VOB general information 1736 for picture objects (or still picture VOB group general information S_VOG_GI), VOB attribute information 1737 for picture objects, and VOBU map 1738 for picture objects (or one or more still picture VOB entries S_VOB_ENT#).

Note that S_VOG_GI contains the number (S_VOB_Ns) of VOBs, a still picture VOB stream information number (S_VOB_STIN), time information (FIRST_VOB_REC_TM) indicating the recording time of the first VOB in that VOB group, time information (LAST_VOB_REC_TM) indicating the recording time of the last VOB in that VOB group, and the start address (S_VOG_SA) of the VOB group in a still picture AV file. S_VOG_SA expresses a relative address from the first address of S_AVFI in units of sectors.

On the other hand, S_VOB_ENT# includes four types (types 1 to 4), which respectively have the following contents:

(1) S_VOB_ENT of type 1 contains information (S_VOB_ENT_TY) indicating the type of VOB entry of a still picture, and information (V_PART_SZ) indicating the video part size in a still picture VOB in units of sectors.

(2) S_VOB_ENT of type 2 contains information (A_PART_SZ) that expresses the original audio part size in a still picture VOB in units of sectors, and information (A_PB_TM) that expresses the playback time of this audio part in units of video fields, in addition to S_VOB_ENT_TY and V_PART_SZ of type 1. When the playback time of an actual audio part does not match a boundary of video fields, data after the video field of end data of the audio part is discarded.

(3) S_VOB_ENT of type 3 contains number information (S_AAGN) of an additional audio group contained in an audio stream added to a still picture VOB, and information (AA_ENTN) of an entry number corresponding to this sill picture VOB additional audio stream, in addition to S_VOB_ENT_TY and V_PART_SZ of type 1.

(4) S_VOB_ENT of type 4 contains S_AAGN and AA_ENTN of type 3 in addition to S_VOB_ENT_TY, V_PART_SZ, A_PART_SZ, and A_PB_TM of type 2.

S_VOB_ENT of each of types 1 to 4 commonly contains S_VOB_ENT_TY and V_PART_SZ of type 1.

Note that each S_AA_STI (#1 to #m) in the left column in FIG. 12 contains audio attribute information of an additional audio stream. From this viewpoint, S_AA_STI corresponds to VOB attribute information 1737 in the right column of FIG. 12.

A plurality of pieces of still picture information grouped to different video objects for picture objects (VOBs for picture objects) are recorded in video object information 1731 for picture objects to video object information 1733 for picture objects (or S_VOGI#1 to S_VOGI#k) in FIG. 12.

The information contents shown in the right column in FIG. 12 will be briefly explained below.

Information 1732 contains the following information:

# VOB general information 1736 for picture objects (or S_VOG_GI) . . .

ID information uniquely set in units of VOBs so as to designate a specific VOB in, e.g., cell playback information (CI in FIG. 1F or S_CI in FIG. 23) 1108;

VOB type information . . . information indicating information shown in FIGS. 10A to 10L to which the VOB belongs, information indicating video information (video objects 1012)/still picture information (picture objects 1013)/audio information (audio objects 1014) to which the VOB pertains, and the date of recording of the VOB on the information storage medium (optical disc 1001);

# VOB attribute information 1737 for picture objects . . .

attribute information such as resolution or the like of still picture and/or attribute information of audio information,

the number of pieces of sub-picture information, recording format, and the like;

# VOB map 1738 for picture objects

information that pertains to all still pictures included in a VOB.

Video object information 1721 for picture objects management information contains the following information:

the number of VOBs for picture objects contained in this AV file;

general information that pertains to VOBs contained in this AV file; and the like.

Also, address data indicating the recording locations of a plurality of pieces of video object information 1731 to 1733 for picture objects in video object information 1107 shown in FIG. 1F are recorded in search pointers 1726 to 1728 of video object information for picture objects.

[9] Data Structure in VOBU Map with respect to Still Picture Information

The data structure in VOBU map 1738 for picture objects will be explained below with reference to FIG. 13.

As shown in the central column of FIG. 13, the number of still pictures contained in the corresponding VOB (i.e., the number of VOBUs; or number of such VOBs S_VOB_Ns) 1801 is stored at the beginning of VOBU map 1738 for picture objects (S_VOB_ENT#).

Information (1802, 1803, 1804, . . . ) that pertains to each still picture (contents of a VOBU) follows in the allocation order in a VOB.

As the information (e.g., 1803) that pertains to each still picture (contents of a VOBU), information shown in the right column in FIG. 13 is recorded.

Referring to FIG. 13, information 1807 of VOBU 1411 (FIG. 3E) having one still picture information which also contains audio information is divisionally recorded on a plurality of sectors 1431 to 1434, as shown in, e.g., FIG. 3F. Data size (V_PART_SZ and/or A_PART_SZ) 1806 for one still picture information (VOBU) is indicated by the number of sectors used in divisional recording.

In case of a VOBU which includes A_PCK (audio pack), as shown in FIGS. 10A to 10C or FIGS. 10D to 10F, display time 1807 of one still picture means (or represents) the playback time of audio information in a VOBU. On the other hand, in case of a VOBU which includes no A_PCK (audio pack), as shown in FIGS. 10G to 10I, display time 1807 means (or represents) the still display period of a still image.

As information that pertains to still image information itself in a VOBU that records one still picture information, the following information (the right column in FIG. 13) is recorded.

# start V_PCK address (or S_VOG_SA) 1808 in the corresponding VOBU

. . . Taking FIGS. 10A to 10L as an example, address data of V_PCKs 1661, 1664, 1665, 1666, 1667, 1668, 1671, 1674, and the like located at the start positions of VOBUs are recorded. When the ID of a VOB that contains a still image the user wants to watch, and the still picture number (VOBU number) in that VOB are designated, an optical head (not shown) directly accesses the start V_PCK address of the corresponding VOBU using this address data.

In general, as address information, the LAN (logical sector number) directly indicating the position on the information storage medium (optical disc 1001) is used, as shown in FIG. 4. However, the present invention is not limited to such specific address indication method, and other application examples are available. For example, as shown in FIG. 9C, the address on the medium may be indicated by the number of sectors (relative address) by counting sectors in the sequence order from the first address of a given VOB in accordance with the sequence order of data.

# I-picture size 1809 in corresponding VOBU

. . . As has been described with reference to FIG. 10C or FIG. 10I, in the data size of I-pictures 1706 and 1707, dummy information 1704 is recorded in a field which is short from an integer multiple of 2,034 bytes as the pack size.

Hence, when the I-picture size is known in advance, the recording location of dummy information 1704 can be detected, and the next location can be accessed without playing back that location, thereby realizing high-speed playback.

# S_PTM (presentation starting time) 1810 of still picture (V_PCK & SP_PCK)

. . . This information indicates the display timing of a still picture and a sub-picture added thereto upon playback. In this embodiment, a still picture recorded in V_PCK and a sub-picture to be added to that picture are simultaneously displayed upon playback. S_PTM is used to set the display timing in relation to audio information in one VOBU.

# First SCR (first system clock) 1811 of still picture (V_PCK)

. . . This information means the system clock value upon creating first V_PCK in a VOBU upon recording on the information storage medium (optical disc 1001), and is used upon executing seamless (continuous) playback.

As information that pertains to audio information in a VOBU which records one still picture information, the following information is recorded.

# first A_PCK address 1812 in VOBU

. . . Taking FIGS. 10A to 10L as an example, address data of, e.g., A_PCKs 1691, 1693, 1694, 1695, 1696, 1699, 1702, and the like located at the start positions of VOBUs are recorded. When the ID of a VOB that contains a still image the user wants to watch, and the still picture number (VOBU number) in that VOB are designated, an optical head (not shown) directly accesses the start V_PCK address of the corresponding VOBU using this address data.

As shown in FIG. 14D, in the present invention, audio information (A_PCK information) in one VOB can be displayed in combination with still picture information that belongs to another VOB. Hence, this information is used when audio information alone in a VOB is selectively played back.

# S_PTM (presentation starting time) 1813 of audio information (A_PCK)

. . . This information indicates the output timing of audio information upon playback. In most cases, this value matches S_PTM 1810 of a still picture (V_PCK & SP_PCK). A different value may be intentionally set when an audio is to be output with a delay of specific time (e.g., 0.5 sec) after a still picture is displayed on the screen.

In this manner, this information (S_PTM) may be used in timing control between the still picture display and audio information output.

# E_PTM (presentation end/terminating time) 1814 of audio information (A_PCK)

. . . This information indicates the output end timing or output termination timing of audio information upon playback, and is used in timing control between the still picture display and audio information output.

In most cases, this value (E_PTM) matches S_PTM 1810 (to be described below) of a still picture (V_PCK & SP_PCK). A different value may be intentionally set when the next still picture information begins to be displayed with a delay of specific time (e.g., 0.5 sec) after ending or termination of the audio output.

# First SCR (first system clock reference) 1815 of audio information (A_PCK)

. . . This information indicates the system clock value upon creating first A_PCK in a VOBU upon recording on the information storage medium (optical disc 1001), and is used upon executing seamless (continuous) playback.

# Last_SCR (last system clock reference) 1816 of audio information (A_PCK)

. . . This information indicates the system clock value upon creating last A_PCK in a VOBU upon recording on the information storage medium (optical disc 1001), and is used upon executing seamless (continuous) playback.

The contents corresponding to A_PB_TM mentioned in the description of S_VOB_ENT in FIG. 12 can be expressed by a pair of First_SCR and Last_SCR above.

In this manner, by recording presentation time PTM information and system clock reference SCR information that respectively pertain to still picture information and audio information, video information that belongs to video objects 1012 shown in FIG. 1D can be used as a part of still picture information.

More specifically, new video object information for picture objects (S_VOB) for a still picture is defined as follows without modifying video information itself that belongs to video objects 1012.

A case will be explained below wherein still pictures that change, for instance, every 2 seconds are defined with respect to the prior video information (video objects 1012).

In general, since the time required for one GOP in video information is 0.5 sec, one VOBU shown in FIG. 3E normally has a duration around 0.5 sec. Since 2 sec÷0.5 sec=4, the leading I-picture of every four VOBUs is considered as a still picture, thus setting information of first V_PCK address 1808 and I-picture size 1809 in a VOB.

Respective numerical values of data in the right column of FIG. 18 may be set similarly.

As a result, by combining and displaying still picture information and audio information that belong to different VOBs (VOB#A and VOB#B), as shown in FIGS. 14A to 14G, only an audio part in video information that belongs to video objects 1012 can be output upon displaying a still picture, or only a scene the user likes in video information that belongs to video objects 1012 can be converted into a still picture, so that the converted still picture can be displayed.

[10] Method of Displaying a Plurality of Still Picture

A method of displaying a plurality of still pictures will be explained below.

As a method of displaying a plurality of pieces of still picture information recorded on the information storage medium (optical disc 1001), a method of simultaneously displaying a plurality of pictures in a given layout (still pictures to be displayed in the given layout are often moved or replaced), as shown in FIG. 11, and a method of displaying one still picture, and changing the still picture to be displayed at specific time intervals are available. In either method, a cell and PGC information are used in the data structure, as shown in FIGS. 6 and 7, and the user can choose the display method by an information recording/playback apparatus (DVD_RTR video recorder) for recording video information shown in FIG. 19.

As in video object information 1107, the contents of cell playback information (or CI) 1108 shown in FIG. 1F are separated into cell playback information (M_CI) that pertains to video information, and cell playback information (S_CI) that pertains to still picture information.

The cell playback information (S_CI) that pertains to still picture information has a structure that can play back a still picture and audio information from different locations, and can present them together, as shown in FIGS. 14A to 14G.

More specifically, in this structure, V_PCKs 1852 and 1854, and SP_PCK 1848 used in display in a given cell can designate still pictures 1832 and 1834 in VOB#A 1821, and audio information output from that cell can designate audio information 1845 and audio information 1846 in VOB#B 1822 which is different from VOB#A 1821, as shown in FIGS. 14C to 14E.

This structure is suitable for after recording setups for a still picture. For example, when still picture information sensed by a digital camera having no audio input function is directly recorded on the information storage medium (optical disc 1001), the resultant recording structure does not contain any A_PCK (audio pack), as shown in FIG. 10I.

A case will be examined below wherein the recorded information is played back, and comments are added to still pictures one by one by “audio input via a microphone”, “overwriting marks by handwriting”, “addition of text information by key-in”, and the like, while displaying them on the screen, as shown in FIG. 11.

In this case, when the recording format is to be changed from the structure that does not contain any A_PCK shown in FIG. 10I to a structure that contains A_PCK shown in FIG. 10F, re-recording must be done on the information storage medium (optical disc 1001), resulting in cumbersome processes and a long processing time.

By contrast, when additional information alone is recorded as another VOB 1634 on the information storage medium (optical disc 1001), as shown in FIGS. 10J to 10L, without modifying the data that does not contain any A_PCK (audio pack) shown in FIG. 10I, information can be added to a still image very easily and quickly later. Upon display, VOBs 1633 and 1634 in FIGS. 10G and 10J are displayed and output together like VOBs 1403 to 1405 in FIG. 3D.

FIG. 15 shows the data structure in cell playback information for picture objects (S_CI) that allows the presentation shown in FIGS. 14A to 14G.

ID information (or CI_SRP) 1873 as an identifier unique to a cell is described first.

Type information (or C_TY) 1880 of a cell described next represents:

1) identification information for identifying cell information that pertains to video information (video objects 1012), cell information that pertains to a still picture (picture objects 1013), or cell information that pertains to only audio information (audio objects 1014); and

2) identification information for identifying cell information (corresponding to the structure shown in FIG. 15) for a VOB that records a plurality of still pictures (the format shown in FIGS. 10D to 10L), or cell information (corresponding to the structure shown in FIG. 16) for a VOB that records only one still picture (the format shown in FIGS. 10A to 10C).

In this way, by absorbing any differences of the recording formats that record still pictures at the level of cell playback information for picture objects (S_CI), both still and moving pictures can be played back and displayed in a single sequence at the level of PGC shown in FIG. 7 beyond the recording format difference of VOBs, irrespective of the still picture information and moving picture information.

In the embodiment shown in FIG. 14A, VOB#A 1821 is designated as ID information 1874 of a VOB shown in FIG. 15 that records video pack V_PCK. When the user wants to display still pictures from the second one in VOB#A 1821, still picture number 2 in VOB#A 1821 is designated as still picture number 1875 to be displayed first in a cell. Also, in correspondence with the embodiment shown in FIG. 14B, still picture number h in VOB#A 1821 is designated as still picture number 1876 to be displayed last in the cell.

In this manner, the cell playback information for picture objects (S_CI) directly designates a “still picture” itself.

In the embodiment show in FIG. 15, “still picture number” is designated as a method of designating a still picture. However, the present invention is not limited to such specific method. For instance, a still picture may be designated by “designating a unit (e.g., a VOBU) itself where a still picture is recorded”, “designating the start address of a location where a still picture is recorded”, “designating the sequence order in a VOB”, and the like.

In FIG. 15, the first and last still pictures in the cell are designated. However, in place of the above display method, the first still picture to be displayed in a cell, and the total number of still pictures to be displayed in that cell may be designated and displayed.

Similarly, in FIG. 15, ID information 1877 (which designates VOB#B 1822 in the embodiment shown in FIG. 14G) of a VOB that records audio pack A_PCK, and still picture number 1878 (which designates still picture number j in the embodiment shown in FIG. 14F) indicating the recording destination of the first audio information (A_PCK) to be output in a cell are described.

In FIG. 15, no still picture number information indicating the recording destination of the last audio information (A_PCK) to be output in the cell is described.

However, the total number of still pictures to be displayed in one cell can be detected, based on still picture number 1875 that indicates the first still picture to be displayed in a cell, and on still picture number 1876 indicating the last still picture to be displayed in the cell. Therefore, the still picture number information indicating the recording destination of A_PCK to be output last in the cell need not be described.

When audio information is designated for all still pictures in FIG. 14D, the presentation time per still picture can be determined by S_PTM 1813 and E_PTM 1814 of audio information shown in FIG. 13. On the other hand, when no audio information is designated for a specific VOBU, the still picture presentation time is set using information of presentation time 1879 per still picture.

Referring to FIG. 15, 1873 to 1876 correspond to the still picture file (RTR_STO.VRO or VR_STILL.VRO) in FIG. 2, and 1877 to 1879 correspond to the after recording audio file (RTR_STA.VRO or VR_AUDIO.VRO) shown in FIG. 2.

[11] Grouping/Displaying Method Applied to Case wherein One Still Picture is Recorded in One VOB

A grouping and displaying method when one VOB records only one still picture will be explained below.

As shown in FIGS. 10A to 10C, when one VOB (video object for picture objects) 1631 records only one still picture, a plurality of VOBs having still pictures are grouped and that group is handled as part_of_title.

This grouping information is recorded in part_of_titles information 1753 (FIG. 8) in video title set information (RTR_VMGI) 1106 shown in FIG. 1F.

The data structures in part_of_titles information 1753 that pertains to still pictures shown in FIG. 17, and in VOB map 1899 for picture objects are similar to those in video object information (S_VOGI#) shown in FIG. 12, and in the VOBU map (S_VOB_ENT#) for picture objects shown in FIG. 13.

Also, the structure of the corresponding cell playback information for picture objects (CI) shown in FIG. 16 is similar to that of S_CI shown in FIG. 15.

One embodiment of an information recording/playback apparatus (RTR video recorder) for recording video information will be explained below.

FIG. 19 is a block diagram for explaining the arrangement in the RTR video recorder.

The apparatus main body of the video recorder shown in FIG. 19 is roughly comprised of disc changer (disc drive unit) 1500 for rotating one to be used of one or more information storage media (optical discs) 1001, and executing recording and playback of video information with respect to optical disc 1001; encoder unit 1550 that constructs the video recording side; decoder unit 1560 that constructs the playback side; and system controller (MPU) 1530 which incorporates a ROM and RAM (semiconductor memory), and controls the operations of the apparatus main body.

Encoder unit 1550 comprises ADC (analog-to-digital converter) 1552, video encoder (V encoder) 1553, audio encoder (A encoder 1554), sub-picture encoder (SP encoder) 1555, formatter 1556, and buffer memory 1557.

ADC 1552 receives an external analog video signal+external analog audio signal from AV input 1542, or analog TV signal+analog audio signal from TV tuner 1544. This ADC 1552 converts the input analog video signal into digital data at, e.g., a sampling frequency=13.5 MHz and the number of quantization bits=8. More specifically, luminance component Y, color difference component Cb (or Y-B or U), and color difference component Cr (or Y-R or V) are respectively quantized by 8 bits.

Likewise, ADC 1552 converts the input analog audio signal into digital data at, e.g., a sampling frequency=48 kHz and the number of quantization bits=16.

When an analog video signal and digital audio signal are input to ADC 1552, the digital audio signal passes through ADC 1552. (A process for reducing jitter superposed on a digital signal, a process for changing the sampling rate and the number of quantization bits, or the like without changing the contents of a digital audio signal may be done.)

When a digital video signal and digital audio signal are input to ADC 1552, these signals pass through ADC 1552 (for these digital signals, a jitter reduction process, sampling rate change process, or the like that do not change their contents may be done).

When still picture information sensed by digital camera 1543 is input in addition to the input video signals, it is directly input to V encoder 1553 without the intervention of ADC 1552.

A digital video signal component output from ADC 1552 is sent to formatter 1556 via video encoder (V encoder) 1553. A digital audio signal component output from ADC 1552 is sent to formatter 1556 via audio encoder (A encoder) 1554. Or a still picture signal directly input to V encoder 1553 is sent from V encoder 1553 to formatter 1556.

V encoder 1553 has a function of converting the input digital video signal into a digital signal compressed at variable bit rate on the basis of the MPEG2 or MPEG1 specifications.

In digital camera 1543, still picture information is recorded in the bitmap or JPEG format. By contrast, in the present invention, a still picture is recorded on optical disc 1001 in the I-picture format of MPEG2. For this purpose, in the present invention, V encoder 1553 has format conversion functions of “bitmap→MPEG2”, “JPEG→MPEG2”, and the like.

A encoder 1554 has a function of converting the input digital audio signal into a digital signal (or linear PCM digital signal) compressed at fixed bit rate on the basis of the MPEG or AC-3 specifications.

When a digital video signal (for example, a signal from a DVD video player with an independent output terminal of a sub-picture signal) is input from AV input 1542, or when a DVD video signal with such data structure is broadcasted and is received by TV tuner 1544, the sub-picture signal component (sub-picture pack) in the video signal is input to sub-picture encoder (SP encoder) 1555. Sub-picture data input to SP encoder 1555 is arranged into a predetermined signal format, and is then sent to formatter 1556.

Formatter 1556 executes predetermined signal processing of the input video signal, audio signal, sub-picture signal, and the like using buffer memory 1557 as a work area, and outputs recording data that matches a predetermined format (file structure) to data processor 1536.

In case of digital broadcast, a video signal is transmitted in the TS (transport stream) format of MPEG2. In general, when a video signal is recorded on information storage medium (optical disc) 1001 in the MPEG2 format, the PS (program stream) format is used. Hence, upon receiving digital broadcast, the received signal is directly sent from TV tuner 1544 to formatter 1556 in which the “TS→PS conversion” is executed.

Standard encode process contents for creating the recording data will be briefly explained below. More specifically, when encoder unit 1550 shown in FIG. 19 starts an encode process, parameters required for encoding video (main picture) data and audio data are set. Main picture data is pre-encoded using the set parameters, and optimal code amount distribution for the selected average transfer rate (recording rate) is calculated. Then, the main picture data is encoded based on the code amount distribution obtained by pre-encoding. At this time, audio data is encoded simultaneously.

As a result of pre-encoding, if it is determined that the data compression amount is insufficient (a desired video program cannot fall within information storage medium (optical disc) 1001 to be used), and pre-encoding can be re-done (if the source to be recorded is a source that can be repetitively played back such as a video tape, video disc, or the like), main picture data is partially re-encoded, and the previously pre-encoded main picture data portion is replaced by the re-encoded main picture data portion. With a series of processes described above, the main picture and audio data are encoded, and the average bit rate value required for recording can be greatly reduced.

Likewise, parameters required for encoding sub-picture data are set, and encoded sub-picture data is generated.

The encoded main picture, audio, and sub-picture data are combined, and are converted into the data structure of desired video objects.

More specifically, a cell as a minimum unit of main picture data (video data) is set, the configuration of cells that form a program chain, attributes of the main picture, sub-picture, and audio data, and the like are set (some of such attribute data use information obtained upon encoding the respective data), and management information that contains various kinds of information which pertain to cells is recorded in the management information recording area (control information 1011 in FIG. 1D or RTR.IFO in FIG. 2).

The encoded main picture, audio, and sub-picture data are segmented into packs each having a predetermined size (2,048 bytes). Dummy packs that can be used in, e.g., after recording, are inserted into these packs as needed. Note that time stamps such as PTS (presentation time stamp), DTS (decode time stamp), and the like are described in packs other than dummy packs, as needed. As for PTS of sub-picture data, a time arbitrarily delayed from PTS of main picture data or of audio data in the identical playback time band can be described.

Data cells are arranged in units of VOBUs to allow playback in the time code order of data, thus forming a VOB consisting of a plurality of cells.

Upon digitally copying video information from the digital output of the DVD_RTR video recorder shown in FIG. 19, since the contents of the cells, program chains, management tables, time stamps, and the like are determined in advance, they need not be created again.

The arrangement for reading/writing (recording and/or playing back) information from/to optical disc 1001 comprises disc drive unit (disc changer) 1500, information recording/reproducing (playing back) unit 101, temporary buffer memory 1534, data processor 1536, and system time counter (or system time clock; STC) 1538.

Temporary buffer memory 1534 is used to buffer a given amount of data to be written on optical disc 1001 (data output from encoder unit 1550) via information recording/reproducing unit 101, and to buffer a given amount of data played back from optical disc 1001 (data input to decoder unit 1560) via information recording/reproducing unit 101.

For example, when temporary buffer memory 1534 comprises a 4-Mbyte semiconductor memory (DRAM), it can buffer recording or playback data for approximately 8 seconds at an average recording rate of 4 Mbps. When temporary buffer memory 1534 comprises a 16-Mbyte EEPROM (flash memory), it can buffer recording or playback data for approximately 30 seconds at an average recording rate of 4 Mbps. Furthermore, when temporary buffer memory 1534 comprises a 100-Mbyte, very small HDD (hard disc drive), it can buffer recording or playback data for 3 minutes or more at an average recording rate of 4 Mbps.

Also, temporary buffer memory 1534 can also be used to temporarily store recording information when optical disc 1001 is used up during video recording, until optical disc 1001 is exchanged by a new disc.

When information recording/reproducing unit 101 uses a high-speed recording/reproducing unit having a speed equal to or higher than double speeds, temporary buffer memory 1534 can also be used to store readout data exceeding a normal amount read out from the drive per unit time.

When temporary buffer memory 1534 buffers readout data upon playback, even when an optical head (not shown) has caused read errors due to vibration shock or the like, playback data buffered by temporary buffer memory 1534 can be used instead, thus preventing a playback image from being discontinued.

If an external card slot (not shown in FIG. 19) is provided to the DVD_RTR video recorder, the EEPROM can be offered as an option IC card. On the other hand, if an external drive slot or SCSI interface is provided to the DVD_RTR video recorder, the HDD can be offered as an option extension drive.

When a personal computer is used as a DVD_RTR video recorder by software, the free area of a hard disc drive or main memory of the personal computer itself can be used as temporary buffer memory 1534 shown in FIG. 19.

Under the control of system controller (MPU) 1530 incorporating ROM and RAM, data processor 1536 shown in FIG. 19 performs:

supply of a video information signal to be recorded from encoder unit 1550 to information recording/reproducing unit 101;

transfer of a video information signal played back by information recording/reproducing unit 101 to another unit;

rewrite of management information (control information 1011) recorded on information storage medium (optical disc) 1001;

partial deletion of video information and/or management information (control information 1011 or RTR.IFO or RTR_VMG) as data recorded on information storage medium (optical disc) 1001; and the like.

System controller 1530 includes an MPU (or CPU), a ROM as an IC memory written with control programs and the like, and a RAM as an IC memory that provides a work area required for executing programs.

Of the execution results of system controller 1530, the contents the user of the DVD_RTR video recorder should know are displayed on display/input panel 1548 of the video recorder.

Incidentally, the control timings of disc changer 1500, information recording/reproducing unit 101, data processor 1536, encoder unit 1550, and/or decoder unit 1560 by system controller (MPU) 1530 can be determined based on time data supplied from STC 1538. Note that video recording/playback are normally executed in synchronism with time clocks from STC 1538, but other processes may be executed at timings independently of STC 1538.

Decoder unit 1560 comprises separator 1562 for separating the respective packs from video information with the pack structure recorded on optical disc 1001; memory 1563 used upon executing pack separation and other signal processes; video decoder (V decoder) 1564 for decoding main picture data (the contents of video packs) separated by separator 1562; sub-picture decoder (SP decoder) 1565 for decoding sub-picture data (the contents of sub-picture packs) separated by separator 1562; audio decoder (A decoder) 1568 for decoding audio data (the contents of audio packs) separated by separator 1562; video processor 1566 for appropriately mixing sub-picture data from SP decoder 1565 with video data output from V decoder 1564, i.e., superposing sub-picture data such as menus, highlight buttons, superimposed dialogs, and the like on main picture data, and outputting them; video digital-to-analog converter (V-DAC) 1567 for converting the digital video output from video processor 1565 into an analog video signal; and audio digital-to-analog converter (A-DAC) 1569 for converting the digital audio output from A decoder 1568 into an analog audio signal.

The analog video signal (analog video information signal) output from V-DAC 1567, and the analog audio signal output from A-DAC 1569 are supplied to an external component (not shown; a multi-channel stereo system having two to six channels+monitor TV or projector) via AV output 1546.

OSD (On Screen Display) data output from system controller (MPU) 1530 is input to separator 1562 in decoder unit 1560, and is then input to video processor 1566 via V decoder 1564 (not decoded). The OSD data is superimposed on main picture data, and they are supplied to an external monitor TV connected to AV output 1546. Thus, a warning message is displayed together with main picture data.

The operations of the information recording/playback apparatus (DVD RTR video recorder) for recording video information shown in FIG. 19 will be described below with reference to the flow charts.

The sequence for recording a plurality of still pictures on information storage medium (DVD_RTR disc) 1001 will be described below with reference to FIG. 20.

Still picture files are continuously input from digital camera 1543 as data (step ST1).

Since each still picture file received from digital camera 1543 is normally recorded in the JPEG or bitmap format, the input still picture information is converted into I-picture data of MPEG2 at V encoder 1553 (step ST2).

Formatter 1556 prepares the VOBU structure with the data structure shown in FIG. 3 with respect to single still picture information, and groups a plurality of still pictures to construct a VOB (step ST3).

Parallel to the aforementioned processes, information recording/reproducing unit 101 reproduces all pieces of control information 1011 (RTR.IFO/RTR_VMG) recorded on optical disc 1001, and saves the reproduced contents in the internal RAM of system controller 1530 (step ST4).

System controller 1530 obtains information of allocation map table 1105 from the contents of control information 1011 saved in its internal RAM, and searches for the location of unrecorded area 1460 (FIG. 4) (step ST5).

After that, system controller 1530 sends control information to formatter 1556, data processor 1536, and information recording/reproducing unit 101, and controls information recording/reproducing unit 101 to record a VOB having a plurality of pieces of still picture information on unrecorded area 1460 (step ST6).

During recording, system controller 1530 monitors the recording state, and checks if the VOB is successfully recorded on optical disc 1001 (step ST7).

If trouble has occurred during recording, the processes of steps ST4 to ST6 are repeated.

If the VOB is successfully recorded on optical disc 1001, system controller 1530 prepares VOBU map 1738 in FIG. 12 (or VOB map 1899 in FIG. 17) on the basis of address information recorded on optical disc 1001 (step ST9).

Finally, VOBU map 1738 (or VOB map 1899) prepared in system controller 1530 is additionally recorded in control information 1011 (RTR.IFO/RTR_VMG) on optical disc 1001 using information recording/reproducing unit 101 (step ST10).

The playback sequence of still picture information containing audio information will be described below with the aid of FIG. 21.

As in steps ST4 and ST5 in FIG. 20, information recording/reproducing unit 101 reproduces all pieces of control information 1011 (RTR.IFO/RTR_VMG) recorded on optical disc 1001, and saves the reproduced contents in the internal RAM (work memory) of system controller 1530 (step ST11).

System controller 1530 obtains information of playback control information 1021 (CI) from the contents of control information 1011 saved in its internal RAM, and interprets the obtained information as to the manner of reproduction (step ST12).

After that, system controller 1530 searches for, from PGC control information 1103 (PGCI) saved in its internal RAM, a program of information to be reproduced. Then, system controller 1530 extracts a cell or cells contained in that PGC information.

Then, VOB_ID or PTT_ID designated by the cell is extracted from cell playback information 1108 saved in RAM (step ST13).

Furthermore, system controller 1530 extracts the recording address of the VOB to be reproduced on optical disc 1001 from video object information 1107 (AVFIT) or part_of_titles information 1753 (FIG. 8) in video title set information 1106 (RTR_VMGI) saved in its internal RAM (step ST14).

The playback sequence for playing back still picture information from VOB#A and presenting audio information recorded in VOB#B simultaneously with the still picture upon playback, as shown in FIGS. 14A to 14G, will be explained.

An optical head (not shown) in information recording/reproducing unit 101 accesses VOB#B recorded on optical disc 1001 on the basis of a control signal from system controller 1530 so as to reproduce the information of VOB#B. Then, audio information for a plurality of still pictures in that reproduced information is temporarily saved in memory 1563 (FIG. 19) (step ST18).

The optical head in information recording/reproducing unit 101 then accesses the information recording position of VOB#A recorded on optical disc 1001 to reproduce still picture information in VOB#A (step ST16).

Finally, AV output 1546 simultaneously outputs (displays) audio information in VOB#B and still picture information in VOB#A (step ST17).

As described above, the method of simultaneously reproducing only audio information for a plurality of still pictures or only still picture information, saving the reproduction result in memory 1562, simultaneously reproducing the remaining information, and outputting (displaying) the reproduction results at the same time is used. With this method, compared to a method of reproducing still picture information and audio information in units of still pictures, the frequency of access of the optical head can be greatly reduced.

As a result of reduction in the frequency of access, it is possible to ensure a seamless and continuous playback (i.e., free from any wait time upon changing the still picture to be displayed, or free from any interrupt of audio information). This is a great feature of this invention.

In FIG. 21 described above, after audio information in VOB#B is reproduced, still picture information in VOB#A is reproduced. However, a modification may be made without departing from the scope of the present invention (e.g., the reproduction order may be replaced).

In the recording format shown in FIGS. 10A to 10L, a pair of still picture information and audio information are saved in a VOBU. However, the present invention is not limited to such specific format. The contents of the present invention can be applied as long as the scope of the invention is implemented.

For example, in case of a recording format in which V_PCKs for a plurality of still pictures may be allocated in the first half of one VOB or in the first half of one PTT, and A_PCKs for a plurality of still pictures are allocated in the second half, then the positions of V_PCK and A_PCK of a still picture with a given number are separated from each other on information storage medium (optical disc) 1001.

In this case, even when still picture information (V_PCK information) and audio information (A_PCK information) with the identical still picture number in one VOB are reproduced in turn, processing of access of an optical head is required.

Therefore, when a plurality of pieces of still picture information are reproduced from picture objects 1013 with the recording format in which V_PCKs for a plurality of still pictures may be allocated in the first half of one VOB or in the first half of one PTT, and A_PCKs for a plurality of still pictures are allocated in the second half, either V_PCK or A_PCK information for a plurality of still pictures is read in advance and saved in memory 1563. Then, the remaining information is reproduced, and the reproduction results can be simultaneously output (displayed), according to the sequence of the present invention.

As another embodiment of the present invention, a method of additionally recording additional information for a still picture by after recording will be explained below with reference to FIG. 22.

Information to be added by after recording forms a group (another VOB or PTT) different from that of original still picture information, and the additional information and still picture information are synthesized and output (displayed) by the method shown in FIGS. 14A to 14G.

Referring to FIG. 22, steps ST11 to ST14 are the same as those in FIG. 21.

In FIG. 22, according to a control signal from system controller 1530, an optical head (not shown) in information recording/reproducing unit 101 accesses a VOB recorded on optical disc 1001 to reproduce its information, and a display as shown by FIG. 11 is performed by AV output 1546 (step ST18).

Additional information input by the user while observing the display screen is received, and a plurality of still pictures are grouped by formatter 1556 on the basis of the input information to construct a VOB or PTT (step ST19).

Finally, VOB information constructed by formatter 1556 is recorded on optical disc 1001 (step ST20).

FIG. 23 is a view for explaining the data structure of navigation data (RTR_VMG) shown in FIG. 8. This RTR_VMG corresponds to control information 1101 and information 1021 in FIG. 1E, and corresponds to control information (RTR.IFO) 1011 in the file structure shown in FIG. 2.

Of this navigation data RTR_VMG, user defined PGC information table UD_PGCIT is comprised of user defined PGC information table information (UD_PGCITI), one or more user defined PGC information search pointers #1 to #n (UD_PGCI_SRP#1 to UD_PGCI_SRP#n), and one or more pieces of user defined PGC information #1 to #n (UD_PGCI#1 to UD_PGCI#n) corresponding in number to these search pointers.

Each user defined PGC information (one of UD_PGCI#1 to UD_PGCI#n) or PGC information #i (PGCI#i) having contents corresponding to original PGC information (ORG_PGCI) is composed of PGC general information (PGC_GI), one or more pieces of program information #1 to #m (PGI#1 to PGI#m), one or more cell information search pointers #1 to #n (CI_SRP#1 to CI_SRP#n), and one or more pieces of cell information #1 to #n (CI#1 to CI#n) corresponding in number to these search pointers.

Each cell information search pointer (one of CI_SRP#1 to CI_SRP#n) contains the start address (CI_SA) of corresponding cell information, and each cell information (one of CI#1 to CI#n) contains movie cell information (M_CI) or still picture cell information (S_CI).

Note that RTR_VMGI in FIG. 23 corresponds to video title set information 1106 in FIG. 1F, M_AVFIT and S_AVFIT in FIG. 23 correspond to video object information 1107 in FIG. 1F, and ORG_PGCI and UD_PGCIT in FIG. 23 correspond to PGC control information 1103 in FIG. 1F.

On the other hand, PGCI#i in FIG. 23 corresponds to PGC control information 1103 in FIG. 1F, and CI# in FIG. 23 corresponds to cell playback information 1108 in FIG. 1F.

FIG. 24 is a view for explaining the contents of still picture cell information (S_CI) in FIG. 23. S_CI contains still picture cell general information (S_C_GI), and one or more pieces of still picture cell entry point information #1 to #n (S_C_EPI#1 to S_C_EPI#n). Note that S_CI in FIG. 24 corresponds to cell playback information 1108 in FIG. 1F.

FIG. 25 is a view for explaining the contents of still picture cell general information (S_C_GI) in FIG. 24.

This S_C_GI contains a cell type (C_TY) which describes the type of cell, the still picture VOB group information search pointer number (S_VOGI_SRPN) of the VOB group used by this cell, the number (C_EPI_Ns) of pieces of cell entry point information in this cell, the start address (S_S_VOB_ENTN) of the still picture VOB entry number of this cell, and the end address (E_S_VOB_ENTN) of the still picture VOB entry number of this cell.

Note that S_S_VOB_ENTN in FIG. 25 corresponds to still picture number 1875 in VOB of FIG. 15, and E_S_VOB_ENTN in FIG. 25 corresponds to still picture number 1876 in VOB of FIG. 15.

FIG. 26 is a view for explaining the contents of each still picture cell entry point information (S_C_EPI) in FIG. 24. This S_C_EPI has two different types (type 1 and type 2).

S_C_EPI of type 1 contains an entry point type (EP_TY) that describes the type of entry point, and still picture VOB entry number (S_VOB_ENTN).

S_C_EPI of type 2 further contains primary text information (PRM_TXTI) in addition to EP_TY and S_VOB_ENTN. This PRM_TXTI can record a comment and other information associated with the corresponding still picture.

Note that S_VOB_ENTN in FIG. 26 is number information which specifies each of one or more still picture VOB entries S_VOB_ENT# (corresponding to VOBU map 1738 for picture objects in FIGS. 12 and 13, or VOB map 1899 for picture objects in FIG. 17).

FIG. 27 is a view for explaining the contents of still picture additional audio file information (S_AAFI) in FIG. 12.

This S_AAFI contains still picture additional audio file information general information (S_AAFI_GI), one or more still picture additional audio group information search pointers #1 to #n (S_AAGI_SRP#1 to S_AAGI_SRP#n), and a plurality of pieces of still picture additional audio group information #1 to #n (S_AAGI#1 to S_AAGI#n) corresponding in number to these search pointers.

Each still picture additional audio group information (one of S_AAGI#1 to S_AAGI#n) contains still picture additional audio group general information (S_AAG_GI), and one or more additional audio entries #1 to #n (AA_ENT#1 to AA_ENT#n).

FIG. 28 is a view for explaining the contents of S_AA_GI general information (S_AAG_GI) in FIG. 27.

This S_AAG_GI contains the number (AA_ENT_Ns) of additional audio entries, the still picture additional audio stream information number (S_AA_STIN), and the start address (S_AAG_SA) of AAG in a still picture additional audio file.

Note that AA_ENT_Ns in FIG. 28 has a value corresponding to number 1801 of still pictures in VOB of FIG. 13 or number 1901 of still pictures in PTT of FIG. 18.

S_AAG_SA in FIG. 28 corresponds to the first still picture address (first still picture information 1802 in VOB or first V_PCK address 1808 in VOBU of FIG. 13; or first still picture information 1902 in PTT or first V_PCK address 1908 in VOB of FIG. 18).

FIG. 29 is a view for explaining the contents of the additional audio entry (AA_ENT) shown in FIG. 27.

This AA_ENT contains an additional audio type (AA_TY) that describes the type of additional audio (e.g., normal one or tentatively created one), the size (AA_SZ) of an additional audio stream, and the playback time (AA_PB_TM) of the additional audio stream.

Note that AA_SZ in FIG. 29 has a value corresponding to the difference between the A_PCK address of the current additional audio (first A_PCK address 1812 in VOBU of FIG. 13 or first A_PCK address 1912 in VOB of FIG. 18), and the A_PCK address of the next additional audio (1812 in FIG. 13 or 1912 in FIG. 18).

On the other hand, AA_PB_TM in FIG. 29 has a value corresponding to the difference obtained by subtracting audio S_PTM 1813 from audio E_PTM 1814 in FIG. 13 (or the difference obtained by subtracting audio S_PTM 1913 from audio E_PTM 1914 in FIG. 18).

FIG. 30 is a view for explaining the contents of still picture VOB group general information (S_VOG_GI) shown in FIG. 12.

This S_VOG_GI contains the number (S_VOB_Ns) of still pictures that describes the number of video parts in the corresponding VOB group, the number (S_VOB_STIN) of pieces of still picture VOB stream information, the time (FIRST_VOB_REC_TM) when the first VOB in that VOB group was recorded, the time (LAST_VOB_REC_TM) when the last VOB in that VOB group was recorded, and the start address (S_VOG_SA) of that VOB group in a still picture AV file.

Note that S_VOB_Ns in FIG. 30 has a value corresponding to number 1801 of still pictures in VOB of FIG. 13 or number 1901 of still pictures in PTT of FIG. 18.

Also, S_VOG_SA in FIG. 30 corresponds to the first still picture address (first still picture information 1802 in VOB or first V_PCK address 1808 in VOBU of FIG. 13; or first still picture information 1902 in PTT or first V_PCK address 1908 in VOB of FIG. 18).

FIG. 31 is a view for explaining the first example (type 1) of the contents of still picture VOB entry (S_VOB_ENT) in FIG. 12.

This S_VOB_ENT of type 1 contains a still picture VOB entry type (S_VOB_ENT_TY) that describes the type of still picture VOB entry, and the size (V_PART_SZ) of the corresponding still picture video part.

Note that S_VOB_ENT_TY contains information MAP_TY that describes the type of S_VOB_ENT, information TE that describes whether the corresponding VOB is in a normal state or in a tentatively erased state (temporarily erased state), and information SPST_Ns that describes the number of sub-picture streams contained (if it is zero, no streams are contained).

On the other hand, V_PART_SZ describes the size of the video part in that VOB in units of sectors.

This V_PART_SZ corresponds to the difference between the address (1808 in FIG. 13) of the first V_PCK in the current still picture VOBU, and the address (1812 in FIG. 13) of the first A_PCK in the current still picture VOBU.

Or, this V_PART_SZ corresponds to the difference between the address (1908 in FIG. 18) of the first V_PCK in the current still picture VOB, and the address (1912 in FIG. 18) of the first A_PCK in the current still picture VOB.

FIG. 32 is a view for explaining the second example (type 2) of the contents of still picture VOB entry (S_VOB_ENT) in FIG. 12.

This S_VOB_ENT of type 2 contains A_PART_SZ that indicates the size of the audio part which is originally attached to the still picture VOB in units of sectors, and A_PB_TM that indicates the playback time of the audio part in units of video fields, in addition to S_VOB_ENT_TY and V_PART_SZ of type 1 shown in FIG. 31.

When the playback time of an actual audio part does not match the boundary of video fields, an excessive piece of end data of the audio part, which piece overflows the video field, is discarded.

Note that A_PART_SZ corresponds to the difference between the first A_PCK address (1812 in FIG. 13) in the current VOBU, and the first V_PCK address (1808 in FIG. 13) in the next VOBU.

Or, A_PART_SZ corresponds to the difference between the first A_PCK address (1912 in FIG. 18) in the current VOB, and the first V_PCK address (1908 in FIG. 18) in the next VOB.

On the other hand, A_PB_TM corresponds to the difference between current S_PTM 1810; FIG. 13 (or current S_PTM 1910; FIG. 18), and next S_PTM 1810; FIG. 13 (or next S_PTM 1910; FIG. 18).

Or, A_PB_TM corresponds to the difference between S_PTM 1813 and E_PTM 1814 in FIG. 13 (or the difference between S_PTM 1913 and E_PTM 1914 in FIG. 18).

FIG. 33 is a view for explaining the third example (type 3) of the contents of still picture VOB entry (S_VOB_ENT) in FIG. 12.

This S_VOB_ENT of type 3 contains the still picture additional audio group number (S_AAGN) and additional audio entry number (AA_ENTN) in addition to S_VOB_ENT_TY and V_PART_SZ of type 1 shown in FIG. 31.

Note that S_AAGN indicates the number of additional audio group that contains the additional audio stream of the corresponding VOB. This S_AAGN corresponds to ID information 1877 of a VOB having A_PCK in FIG. 15.

On the other hand, AA_ENTN indicates the number of additional audio entry corresponding to the additional audio stream of the corresponding VOB. This AA_ENTN corresponds to still picture number 1878 in a VOB that contains A_PCK of the first still picture in a cell of FIG. 15.

FIG. 34 is a view for explaining the fourth example (type 4) of the contents of still picture VOB entry (S_VOB_ENT) in FIG. 12.

This S_VOB_ENT of type 4 has contents that combine S_VOB_ENT_TY and V_PART_SZ of type 1 shown in FIG. 31, A_PART_SZ and A_PB_TM of type 2 shown in FIG. 32, and S_AAGN and AA_ENTN of type 3 shown in FIG. 33.

In entries S_VOB_ENT of types 1 to 4 shown in FIGS. 31 to 34, the same field names (S_VOB_ENT_TY, etc.) have the same contents.

FIG. 35 is a view for explaining the relationship between the original PGC information (ORG_PGCI in FIG. 8 or 23) and still picture video file (RTR_STO.VRO in FIG. 2) when only still picture VOBs are recorded.

In an original PGC where only still picture VOBs are recorded, the PGCI consists of a sequence of cells, and each cell corresponds to a still picture VOB group.

Still picture VOB group is introduced to reduce the navigation data size associated with each still picture VOB, considering when a huge number of still picture VOBs are recorded.

However, a cell is unable to refer to both movie VOB and still picture VOB at the same time. Therefore, if a movie VOB and a still picture VOB is recorded alternatively, a still picture VOB group may contain only one still picture VOB.

Assume that still picture VOB group information S_VOGI#2 in FIG. 35 corresponds to VOBs 1631 to 1633 in FIGS. 10A to 10L.

Under this assumption, for example, VOBU 1641 in FIG. 10B, VOBU 1644 in FIG. 10E, and VOBU 1646 in FIG. 10H are contained in S_VOGI#2. The video part in still picture VOB group #2 in FIG. 35 corresponds to packs 1661 to 1663 and 1681 in FIG. 10C, pack 1665 in FIG. 10F, or packs 1668 to 1670 and 1683 in FIG. 10I.

Also, assume that S_VOGI#2 in FIG. 35 corresponds to VOB#A in FIG. 14A.

Under this assumption, for example, still picture number 2 of VOBU 1862 in FIG. 14B corresponds to VOB entry number 2 of S_VOGI#2, packs 1852, 1848, and 1862 of still picture 1832 in FIG. 14C correspond to central video and audio parts of the RTR_STO.VRO file in FIG. 35, and pack 1853 of still picture 1833 in FIG. 14C corresponds to a trailing video part of the RTR_STO.VRO file.

FIG. 36 is a view for explaining the relationship between the original PGC information (ORG_PGCI) and still picture additional audio part (RTR_STA.VRO in FIG. 2).

VOB entry contains access information to the associated video part and the audio part both of which are recorded in the RTR_STO.VRO file. The audio part is recorded immediately after the associated video part.

When an additional audio part associated with a video part is recorded in RTR_STA.VRO file, an additional audio entry is described in data fields other than the VOGI, and a link from the VOB entry to the additional audio entry is described in the VOB entry.

Assume that additional audio file RTR_STA.VRO in FIG. 36 corresponds to VOB#B in FIG. 14G.

Under this assumption, for example, the arrow from A_PCKs 1865 and 1866 in FIG. 14D to A_PCKs 1865 and 1866 in FIG. 14E corresponds to that from a VOB entry in S_VOGI#2 in FIG. 36 to its right neighboring additional audio entry.

In this case, paying attention to the arrow of A_PCK 1866, A_PCK 1866 in FIG. 14E corresponds to the central audio part of RTR_STA.VRO in FIG. 36, and still picture number h+j−2 in FIG. 14F constructs a part corresponding to A_PCK 1866 of the additional audio entry in FIG. 36.

The information parts (the VOB entry and additional audio entry in FIG. 36) connected by the arrows can be linked using cell playback information 1108 in FIG. 1F or S_CI in FIG. 24.

When the central audio part in the RTR_STA.VRO file in FIG. 36 is audio information of after recording, A_PCK 1866 in FIG. 14E corresponding to this audio part can be constructed using dummy pack DM_PCK shown in FIG. 3F.

FIG. 37 is a view for explaining an example of the structure of original PGC information (ORG_PGCI in FIG. 8 or 23) that contains still picture VOBs (RTR_STO.VRO file) and movie VOBs (RTR_MOV.VRO file).

Assume that program #1 of PGCI#1 in FIG. 37 corresponds to VTS 1762 in FIG. 9E, S_VOGI#1 and S_VOGI#2 correspond to VOB#D 1774 and VOB#E 1775 in FIG. 9F, and M_VOBI#1 and M_VOBI#2 correspond to VOB#A 1771 and VOB#B 1772 in FIG. 9F.

Under this assumption, picture object 1013 in FIG. 9F constructs the contents (video and audio parts) of the RTR_STO.VRO file in FIG. 37, and video object 1012 in FIG. 9F constructs the contents (VOB#1, VOB#2, . . . ) of the RTR_MOV.VRO file in FIG. 37.

Referring to FIG. 37, cell# in PGCI and VOB entries in S_VOGI# can be linked using, e.g., S_S_VOB_ENTN and E_S_VOB_ENTN in FIG. 25.

On the other hand, the logical addresses of the video or audio part in the RTR_STO.VRO file, and VOB numbers designated by VOB entries in S_VOGI# can be linked using the relationships shown in, e.g., FIGS. 4 and 5.

Time map TMAP in M_VOBI# in FIG. 37 will be explained below.

Although not shown by a figure, movie AV file information table M_AVFIT in FIG. 8 or 23 contains movie AV file information general information (M_AVFI_GI), one or more movie VOB information search pointers (M_VOBI_SRP#1 to M_VOBI_SRP#n), and one or more pieces of movie VOB information (M_VOBI#1 to M_VOBI#n) corresponding in number to these search pointers.

Each M_VOBI# contains movie VOB general information (M_VOBI_GI), seamless information (SMLI), audio gap information (AGAPI), and time map information (TMAPI) (not shown).

This TMAPI is used upon executing special playback (e.g., cell playback in the order unique to the user using user defined PGC) and time search.

TMAPI contains time map general information (TMAP_GI), one or more time entries (TMENT#1 to TM_ENT#r), and one or more VOBU entries (VOBU_ENT#1 to VOBU_ENT#q) (not shown).

Each VOBU entry contains information that pertains to the size and playback time of each VOBU. The VOBU size is indicated in units of sectors (2 k bytes or 2,048 bytes), and the playback time is indicated in units of video fields ({fraction (1/60)} sec per field in NTSC; {fraction (1/50)} sec per field in PAL).

Since the VOBU size is indicated in units of sectors, as described above, each VOBU can be accessed using an address in units of sectors.

Each VOBU entry contains reference picture size information 1STREF_SZ, VOBU playback time information VOBU_PB_TM, and VOBU size information VOBU_SZ (not shown).

Note that VOBU_PB_TM expresses the playback time of the VOBU of interest in units of video fields. On the other hand, reference picture size information 1STREF_SZ expresses the size of the first reference picture (corresponding to I-picture of MPEG) of that VOBU in units of sectors.

On the other hand, each time entry contains address information (VOBU_ADR) of the corresponding VOBU, and time difference information (TM_DIFF) (not shown). This time difference information indicates the difference between the playback time designated by a time entry, and the playback start time of a VOBU.

Assuming that the time interval (time unit TMU) between two successive time entries is 10 sec, this time entry interval corresponds to, e.g., 600 fields in NTSC video.

Normally, the “time interval between neighboring VOBUs” is expressed by the number of fields in the VOBU entry. As another method, “count value from a given VOBU to the next VOBU by a clock counter” may be used to express the “time interval between neighboring VOBUs”.

For example, the “time interval between neighboring VOBUs” can be expressed by the “difference value between the value of presentation time stamp PTS at the start position of one VOBU and the value of PTS at the start position of the immediately succeeding VOBU”.

In other words, the time interval in a specific unit can be expressed by the count-difference value of the clock counter in that unit.

Time map generation information TMAP_GI includes TM_ENT_Ns indicating the number of time entries in that time map information, VOBU_ENT_Ns indicating the number of VOBU entries in that time map information, time offset TM_OSF for that time map information, and address offset ADR_OFS of that time map information (not shown).

When a value (10 seconds or its equivalent) corresponding to 600 fields in NTSC video (or 500 fields in PAL video) is used as time unit TMU, time offset TM_OSF is used to represent the time offset within TMU.

When the VOBU size is expressed by the number of sectors, address offset ADR_OFS is used to indicate a file pointer from the beginning of an AV file.

Time entry TM_ENT includes VOBU_ENTN indicating the number of the corresponding VOBU entry, TM_DIFF indicating the time difference between the playback start time of VOBU designated by the time entry and the calculated playback time, and VOBU_ADR indicating the target VOBU address (not shown).

When time unit TMU is expressed by 600 fields in NTSC (or when time unit TMU is expressed by 500 fields in PAL), the “calculated playback time” with respect to time entry #j is given by TMU×(j−1)+TM_OSF.

On the other hand, VOBU_ADR indicates the target VOBU address by the total size of preceding VOBUs in VOB of interest when the VOBU size is expressed in units of sectors.

In the aforementioned data structure, in order to start playback from the middle of a certain VOBU, that access point must be determined. This access point is assumed to be a time entry point.

This time entry point is located at a position separated from the position indicated by movie address information of the VOBU by the time difference indicated by time difference information TM_DIFF in time entry TM_ENT. This time entry point serves as a special presentation start point (or time search point) indicated by time map information TMAPI.

Cell# in PGCI in FIG. 37 and time map TMAP in M_VOBI# can be linked in the same manner as S_VOGI#.

FIG. 37 illustrates a case wherein a video field corresponding to the presentation start time is in the middle of VOBU#k. In order to display a sequence of video fields from the video field specified by the presentation start time, the VOBU data from the beginning need to be input to the decoder. This is because the decoder need to decode all of the reference video fields which have presentation time earlier than the presentation start time, even though the decoded fields may not be displayed. When the decoding reaches to the video field corresponding to the presentation start time, the decoder starts the display of video pictures.

This capability to start display exactly at the video field corresponding to the presentation start time is not mandatory, but it is recommended to constitute an apparatus (or system) to enable this capability.

FIG. 38 is a view for explaining a case wherein user defined PGC Information (FIG. 6) refers to a still picture VOB group.

A user defined PGC may include two types of cells, each of which refers to a movie VOB or a still picture VOB group.

FIG. 38 shows an example of user defined PGC which refers to still picture VOB. In the figure, cell#1 in the user defined PGC refers to still picture VOB group #2.

The cell#2 in the original PGC refers to the whole still picture VOB group #2 by specifying the first still picture VOB number and the last still picture VOB number in the still picture VOB group. However, the cell#1 in the user defined PGC refers to only a still picture VOB in the VOB group by specifying the second still picture VOB as the first still picture VOB number and the last still picture VOB number.

Assume that PGCI in FIG. 38 corresponds to PGC (or PGCI) 1446 in FIG. 3H. In this case, cell#1 and cell#2 in PGCI in FIG. 38 correspond to cells 1441 and 1442 in FIG. 3G. On the other hand, the first video part in the RTR_STO.VRO file in FIG. 38 corresponds to a cluster (extent) of V_PCK 1421 and SP_PCK 1422 in FIG. 3F. Furthermore, a video part that follows the first video part corresponds to a cluster (extent) of A_PCK 1423 and DM_PCK 1424 in FIG. 3F.

The characteristic features of the respective embodiments of the present invention will be summarized below.

a] One VOB or PTT can contain a plurality of pieces of still picture information.

b] Upon recording a plurality of still pictures, one VOB can continuously record at least two pieces of still picture information in an unrecorded area thereof.

c] Cell information (S_CI) can designate a plurality of pieces of continuous still picture information.

The effects of these a] to c] are common to the respective embodiments.

More specifically, a high-performance digital camera can record several thousand or several ten thousand still pictures. Upon transferring data to an optical disc, the data are preferably grouped and recorded on an optical disc in units of a plurality of still pictures, thus allowing easy processing and attaining short transfer time.

A high-performance digital camera can record several thousand or several ten thousand still pictures. When VOB information is prepared by constructing a VOB for each still picture, management information has a huge size. The method of the present invention can greatly reduce the management information size.

Furthermore, since each still picture information forms a different file in the digital camera, management and search processes are cumbersome. In the present invention, since still pictures are grouped in units of a plurality of pictures, management and search processes are easy.

Since each still picture information forms a different file in the digital camera, the contents of a still picture cannot be confirmed unless each file is opened. In the present invention, the user can confirm contents as if he or she checked a positive film (or negative film) of photographs, as shown in FIG. 11, by grouping still pictures in units of a plurality of pictures.

Furthermore, video information that stretches across a plurality of video frames is recorded in units of VOBs. When information of a plurality of still pictures are recorded in units of VOBs, video information and still picture information can be processed in a single layer (in a single directory level in FIG. 2). For example, cells of both video information and still picture information can be allocated in a single PGC, thus allowing mixed display of video information and still picture information, and broadening or expanding the range of expression/presentation.

d] In the embodiment of the present invention, the vOBU map (S_VOB_ENT#) or VOB map is prepared.

e] The DVD_RTR recorder has an arrangement capable of recording the VOBU map or VOB map.

The effects of these d] and e] are common to the respective embodiments.

The user can directly access a still picture he or she wants to watch using the VOBU map or VOB map that records information such as recording addresses in units of still pictures, and the access speed for displaying a plurality of still pictures can be greatly improved.

When a plurality of still pictures are to be continuously displayed, seamless display (with continuous joints among still pictures) can be achieved using presentation (playback) time information (PTM) and/or system clock reference information (SCR).

Furthermore, since the start addresses of V_PCK that records a still picture itself and A_PCK that records audio information are described at different locations, high-speed access can be made when only still picture information or audio information is to be played back. As a result, when audio information in a specific VOB is multiply used to display still picture in another VOB (since audio information alone can be accessed at high speed), seamless display can be made.

f] In the present invention, cell information (S_CI) designates each still picture in a VOB.

For this reason, since each still picture itself can be designated upon playback (using the VOBU map or VOB map), high-speed access can be performed, and seamless display can be made when a plurality of still pictures are to be displayed in turn.

Since each still picture itself can be designated upon playback, management upon playback becomes very easy. For example, upon displaying a plurality of still pictures on the screen at one time, as shown in FIG. 11, the processing to be executed becomes simple.

g] In the present invention, cell information (S_CI) can multiply designate a plurality of pieces of still picture information in different VOBs.

For this reason, since continuous audio information in one VOB can be used upon displaying another VOB, the expression range can be broadened.

Furthermore, since continuous audio information in one VOB can be used upon displaying another VOB, common data can be used and, hence, the data size to be recorded on the information storage medium (optical disc 1001) can be reduced. As a result, the actual data size that can be recorded per information storage medium (optical disc 1001) can be greatly increased.

By only preparing new video object information (S_AVFIT) for picture objects corresponding to the already-recorded video information, the existing video information can be used in combination with still picture information, without modifying the already-recorded video objects 1012 themselves.

h] In the present invention, cell information is reproduced, and a still picture is played back using VOB information (VOBI).

As a consequence, since cell playback information for picture objects (S_CI) can be set independently of video object information for picture objects as management information of the contents of picture objects 1013, the playback order can be designated irrespective of the recording order of still pictures on the information storage medium (optical disc 1001), thus remarkably improving the degree of freedom in expression/presentation.

i] The present invention provides an apparatus which reads out still picture information and audio information from a memory, and can simultaneously play back the still picture information and audio information.

When a plurality of pieces of still picture information in different VOBs are to be designated, or when audio information alone for a plurality of still pictures is recorded on another area, if V_PCK, SP_PCK, and A_PCK are played back in turn in units of still pictures, the frequency of access becomes very high, and it is hard to continuously display a plurality of still pictures in turn (due to the influence of the access wait time of the optical head).

By contrast, when information contents for at least two still pictures of V_PCK, SP_PCK, and A_PCK are played back at the same time, and are temporarily saved in memory 1563, and the stored contents are displayed simultaneously with the playback timing of the remaining information, the frequency of access of the optical head can be greatly reduced, thus allowing easy continuous display.

j] The present invention provides an after recording apparatus for recording additional information to already recorded still pictures.

For example, when still picture information sensed by a digital camera having no audio input function is directly recorded on the information storage medium (optical disc 1001), the recording result has a structure which does not contain any A_PCK (audio pack), as shown in FIG. 10I.

A case will be examined below wherein the recorded information is played back, and comments are added to still pictures one by one by “audio input via a microphone”, “overwriting marks by handwriting”, “addition of text information by key-in”, and the like, while displaying them on the screen, as shown in FIG. 11.

In this case, when the recording format is to be changed from the structure that does not contain any A_PCK shown in FIG. 10I to a structure that contains A_PCK shown in FIG. 10F, re-recording must be done on the information storage medium (optical disc 1001), resulting in cumbersome processes and a long processing time. By contrast, when additional information alone is recorded as another VOB 1634 on the information storage medium (optical disc 1001), as shown in FIG. 10J, without modifying the data that does not contain any A_PCK (audio pack) shown in FIG. 10I, information can be added to a still image very easily and quickly later.

FIG. 39 is a view for explaining protect information for protecting a program and the storage location of the protect information.

As shown in FIGS. 1D and 1E, control information (RTR.IFO) 1011 recorded on DVD-RTR disc 1001 contains navigation data RTR_VMG.

As shown in FIG. 1F or 8, navigation data RTR_VMG contains PGC information (original PGC information ORG_PGCI and user defined PGC information table UD_PGCIT).

As shown in FIG. 6, each PGC information (UD_PGCI#i) contains one or more pieces of program information (PGI#1, PGI#2, . . . , PGI#m).

As shown in FIG. 23, the original PGC information or user defined PGC information (to be referred to as PGC information PGCI altogether) contain one or more pieces of program information (PGI#1, PGI#2, . . . , PGI#m).

In this information hierarchy, as shown in FIG. 39, each program information (e.g., PGI#1) contains program type PG_TY, number of cells C_Ns in program PG, primary text information PRM_TXTI, item text search pointer number IT_TXT_SRPN, and thumbnail pointer information THM_PTRI.

Program type PG_TY of each program information PGI# describes protect information (erase prohibition flag) for protecting the corresponding program from unintentional or erroneous erase.

When the protect information flag is set at 0b, the corresponding program is not protected so that this program is in an erasable (or rewritable) state.

When the protect information flag is set to 1b, this program is changed to an unerasable (or unrewritable) state wherein the program is protected from, e.g., unintentional or erroneous erase. However, the program whose protect information flag is set to 1b can be reproduced or played back.

The protect information in FIG. 39 can be processed as attribute information of each program (PGI#).

FIG. 40 is a view for explaining a temporary erase flag (TE) for a still picture and the storage location of the temporary erase flag.

As described above, control information (RTR.IFO) 1011 recorded on DVD_RTR disc 1001 contains navigation data RTR_VMG.

As shown in FIG. 1F or 8, navigation data RTR_VMG contains AV file information (movie AV file information table M_AVFIT and still picture AV file information table S_AVFIT).

As shown in FIG. 12, still picture AV file information table S_AVFIT contains one or more pieces of still picture VOB group information (S_VOGI#1, S_VOGI#2, . . . )

In this information hierarchy, as shown in FIG. 40, each still picture VOB group information (e.g., S_VOGI#1) contains still picture VOB group general information S_VOG_GI and one or more pieces of still picture VOB entries (S_VOB_ENT#1, . . . , S_VOB_ENT#n).

Each still picture VOB entry (e.g., S_VOB_ENT#1) belongs to any one of types 1 to 4 of FIGS. 31 to 34. In any case, this still picture VOB entry contains still picture VOB entry type S_VOB_ENT_TY.

This S_VOB_ENT_TY describes map type MAP_TY indicating to which of types 1 to 4 in FIGS. 31 to 34 this S_VOB_ENT_TY belongs, temporary erase flag TE, and number of sub-picture streams SPST_Ns.

When temporary erase flag TE is set at 0b, the VOB group is in a normal state so that the VOB group can be played back.

When temporary erase flag TE is set to 1b, this VOB group is removed from playback targets (or masked), and changes to a state in which the VOB group is not played back (or a state in which the VOB group is not actually erased but is skipped in playback as if the VOB group were erased). However, a VOB group whose temporary erase flag TE is set to 1b or a program comprised of such a VOB group can be played back or reproduced by re-setting the flag TE to 0b.

Temporary erase flag TE in FIG. 40 can be processed as attribute information of a corresponding VOB group or program comprised of this VOB group.

FIG. 41 is a view for explaining a case wherein part of protected program PG#2 is re-set to an erasable state and temporarily erased state.

In the example of FIG. 41, programs PG#1 to PG#3 before changing the protect (erase prohibition) range are laid out as follows:

(1) Program PG#1=VOB group VOG#A comprised of still pictures A1, A2, . . . ;

(2) Program PG#2=VOB group VOG#B (protected to prohibit an erase) comprised of still pictures B1 to B162+VOB group VOG#C (protected to prohibit an erase) comprised of still pictures C1 to C9; and

(3) Program PG#3=VOB group VOG#D comprised of still pictures D1 . . . .

The playback order in this case is PG#1→PG#2→PG#3 depending on corresponding PGC information (PGCI).

In the above example, programs PG#1 to PG#5 after changing the protect (erase prohibition) range are relaid out as follows:

(1) Program PG#1=VOB group VOG#A comprised of still pictures A1, A2, . . . ;

(2a) Changed program PG#2=VOB group VOG#B (protected to prohibit an erase) comprised of still pictures B1 to B80;

(2b) New program PG#4=new VOB group VOG#E (protection is canceled, and an erasable state is set) comprised of still pictures B81 to B99;

(2c) New program PG#5=new VOB group VOG#F (temporary erase flag TE is set to 1b so as not to play back VOB group VOG#F) comprised of still pictures B100 to B162+VOB group VOG#C (temporary flag TE is set to 1b so as not to play back VOB group VOG#C) comprised of still pictures C1 to C9; and

(3) Program PG#3=VOB group VOG#D comprised of still pictures D1 . . . .

The playback order in this case is PG#1→PG#2→PG#4→PG#3 depending on the changed PGC information (PGCI) (where playback of PG#5 whose temporary erase flag TE is set to 1b is skipped).

In the management information recording area (S_VOGI in FIG. 40) that describes VOG attribute information, attribute information (MAP_TY, TE, SPST_Ns) of each target still picture is recorded in S_VOB_ENT. Part (temporary erase flag TE) of this attribute information allows setting each still picture to a temporarily erased state.

In playback, no temporarily erased still picture is displayed on the playback monitor screen (FIG. 11). For example, assume that a sports car picture, personal computer picture, and running businessman picture in FIG. 11 are still pictures C8, C9, and D1 in FIG. 41, respectively. Further, assume that still picture C8 and its preceding still pictures, and still picture D1 and its subsequent still pictures have temporary erase flag TE of 0b, and temporary erase flag TE (TE=1b) is set for only still picture C9 (personal computer picture in FIG. 11).

In this case, still pictures are played back sequentially from still picture A1 of PG#1 in FIG. 41 (in FIG. 11, the display is scrolled left). Still picture C8 (sports car picture) and still picture D1 (running businessman picture) are sequentially played back. Still picture C9 (personal computer picture which is not actually erased but is in a temporarily erased state) is not displayed on the playback screen. In this case, a user watches the monitor in FIG. 11 as if the running businessman picture were laid out immediately after the sports car picture (without any space).

One or more still pictures recorded on recording medium (optical disc) 1001 in FIG. 1A are grouped into a VOB group (VOG) and managed in units of groups.

All pieces of AV information recorded on medium 1001 can be sequentially played back based on original PGC information. This original PGC information is comprised of one or more programs.

The erase prohibition flag (protect information in FIG. 39) can be set in unit of a program.

All still pictures contained in a program whose erase prohibition flag is set (protect information=1b) are changed to an erase prohibition state.

To return some of still pictures in an erase prohibition state to an erasable state, “re-setting of VOB group (VOG)” and “re-setting of program” have to be executed. Examples of “re-setting of VOB group (VOG)” and “re-setting of program” will be described.

FIG. 42 is a flow chart for explaining an example of the sequence for re-setting part of protected program PG#2 to an erasable state and temporarily erased state. This processing can be executed by the internal MPU of system controller 1530 in FIG. 19. The sequence of FIG. 42 will be explained with reference to FIG. 41.

Assume that program PG#2 is composed of VOG#B including still pictures B1 to B162 and VOG#C including still pictures C1 to C9, and this PG#2 is protected (or erase is prohibited).

The protect state and temporarily erased state of program PG#2 can be changed by the following sequence.

More specifically, in FIG. 42, the range of still pictures within VOG#B is re-defined from still picture B1 to still picture B80 (step ST100).

The VOB group within PG#2 is re-set as VOG#B only (step ST102).

The range of still pictures is re-grouped from B81 to B99 as new VOG#E (step ST104).

New program PG#4 formed of VOG#E only is defined (step ST106). At this time, no temporary erase flag TE is set for new PG#4, and VOG#E is in an erasable (of course, playback enable) state.

The range of still pictures is re-grouped from B100 to B162 as new VOG#F (step ST108).

New program PG#5 formed of VOG#F and VOG#C is defined (step ST110).

Finally, temporary erase flag TE is set to PG#5 (step ST112), and the processing of FIG. 42 is completed.

In program PG#2 of FIG. 41 before processing of FIG. 42, all still pictures B1 to B162 are in unerasable (but playback enable) state.

To the contrary, in program PG#2 of FIG. 41 after processing of FIG. 42, only still pictures B1 to B80 are in an unerasable (but playback enable) state, and remaining still pictures B81 to B162 are changed to an erasable (also playback enable) state, as needed.

Further, in program PG#2 of FIG. 41 after processing of FIG. 42, still pictures B100 to B162 and C1 to C9 are changed to a temporarily erased state (wherein still pictures cannot be played back and can be actually erased because they are not protected).

The characteristic features of the above-described embodiments will be summarized below.

<01> One VOB contains a plurality of pieces of still picture information, or one PTT contains a plurality of pieces of still picture information.

<02> Upon recording a plurality of still pictures, one VOB can continuously record at least two pieces of still picture information in an unrecorded area of a recording medium.

<03> Cell information (S_CI in FIG. 23 or 24) can designate a plurality of pieces of continuous still picture information.

<04> The VOBU map or VOB map is prepared.

<05> Cell information (S_CI) designates each still picture in a VOB.

Since each still picture itself can be designated upon playback (using the VOBU map or VOB map), high-speed access can be performed, and seamless display (e.g., smooth slide show) can be made when a plurality of still pictures are to be displayed in turn.

Since each still picture itself can be designated upon playback, management upon playback becomes very easy. For example, upon displaying a plurality of still pictures on the screen at one time, as shown in FIG. 11, the processing to be executed becomes simple.

<06> Cell information (S_CI) can multiply designate a plurality of pieces of still picture information in different VOBs.

Since continuous audio information in one VOB can be used upon displaying another VOB, the expression range can be broadened or expanded.

Since continuous audio information in one VOB can be used upon displaying another VOB, common data can be used and, hence, the data size to be recorded on the information storage medium (optical disc 1001) can be reduced. As a result, the data size that can be recorded per information storage medium can be greatly increased actually.

By only preparing new video object information for picture objects corresponding to the already recorded video information, the existing video information can be used in combination with still picture information, without modifying video objects 1012 themselves.

<07> Cell information (S_CI) is reproduced, and a still picture is played back using VOBI.

Cell playback information for picture objects can be set independently of video object information for picture objects as management information of the contents of picture objects 1013. Since the playback order can be designated irrespective of the recording order of still pictures on the information storage medium (optical disc 1001), the degree of freedom in expression is remarkably improved.

<08> An apparatus which reads out still picture information or audio information from a memory, and simultaneously plays back the still picture information and audio information is provided.

When a plurality of pieces of still picture information in different VOBs are to be designated, or when audio information alone for a plurality of still pictures is recorded on another area, if V_PCK, SP_PCK, and A_PCK are played back in turn in units of still pictures, the frequency of access becomes very high, and it is hard to continuously display a plurality of still pictures in turn (due to the influence of the access wait time of an optical head; not shown).

By contrast, when information contents for at least two still pictures of V_PCK, SP_PCK, and A_PCK are played back at the same time, and are temporarily saved in memory 1563 of FIG. 19, and the stored contents are displayed simultaneously with the playback timing of the remaining information, then the frequency of access of the optical head can be greatly reduced, thus allowing easy continuous display.

<09> An after recording apparatus for recording additional information to already recorded still pictures is provided.

For example, when still picture information sensed by a digital camera having no audio input function is directly recorded on the information storage medium (optical disc 1001), the recording result has a structure which does not contain any audio pack (A_PCK).

Assume a case where the recorded information is played back, and comments are added to still pictures one by one by “audio input via a microphone”, “overwriting marks by handwriting”, “addition of text information by key-in”, and the like, while displaying them on the screen, as shown in FIG. 11. In this case, when the recording format is to be changed from the structure that does not contain any A_PCK to a structure that contains A_PCK, re-recording must be done on the information storage medium, resulting in cumbersome processes and a long processing time.

By contrast, when additional information alone is recorded as another VOB on the information storage medium without modifying the data that does not contain any A_PCK, information can be added to a still picture very easily and quickly later.

As has been described above, the management system of the present invention can provide the following advantages:

(1) The system can adopt a data structure similar to that of a DVD video disc and can therefore assure compatibility and continuity with the DVD video disc to some extent.

(2) The system can adopt similar data structures between moving and still pictures and thus can assure consistency or continuity of a recording format and management information.

(3) The system can manage protection and temporary erase of digital information pertaining to a plurality of pieces of still picture information.

Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents. 

What is claimed is:
 1. A method for recording information on an information storage medium capable of recording and playing back at least still picture information, comprising the steps of: recording on the medium at least one picture object containing still picture information and control information, the control information including: a still picture AV file information table S_AVFIT which includes still picture AV file information S_AVFI, the still picture AV file information S_AVFI including: a section of general information S_AVFI_GI for picture object management; at least one search pointer S_VOGI_SRP#i which describes a start address of video object group information S_VOGI; and at least one video object information for picture object S_VOGI#i, the at least one video object information for picture objects S_VOGI#i including: still picture VOB group general information S_VOGI_GI containing information of a still picture VOB group, and a still picture VOB entry S_VOB_ENT# which contains information of how to access objects including pictures, the at least one video object information for picture objects S_VOGI#i including information of an address of a first still picture S_VOG_SA and a size of a picture, said still picture VOB entry S_VOB_ENT# including temporary erase information TE which indicates whether a still picture VOB corresponding to said still picture VOB entry S_VOB_ENT# is in a temporarily erased state.
 2. A method according to claim 1, wherein the still picture VOB group general information S_VOGI_GI and the still picture VOB entry S_VOB_ENT# are included in information of a still picture in a corresponding VOB which includes the information of an address of a first still picture S_VOG_SA and the size of the picture.
 3. A system for recording information on an information storage medium capable of recording and playing back at least still picture information, comprising: means for recording on the medium at least one picture object containing still picture information and means for recoding on the medium control information, the control information including: a still picture AV file information table S_AVFIT which includes still picture AV file information S_AVFI, the still picture AV file information S_AVFI including: a section of general information S_AVFI_GI for picture object management; at least one search pointer S_VOGI_SRP#i which describes a start address of video object group information S_VOGI; and at least one video object information for picture object S_VOGI#i, the at least one video object information for picture objects S_VOGI#I including: still picture VOB group general information S_VOGI_GI containing information of a still picture VOB group, and a still picture VOB entry S_VOB_ENT# which contains information of how to access objects including pictures, the at least one video object information for picture objects S_VOGI#i including information of an address of a first still picture S_VOG_SA and a size of a picture, said still picture VOB entry S_VOB_ENT# including temporary erase information TE which indicates whether a still picture VOB corresponding to said still picture VOB entry S_VOB_ENT# is in a temporarily erased state.
 4. A system according to claim 3, wherein the still picture VOB group general information S_VOGI_GI and the still picture VOB entry S_VOB_ENT# are included in information of a still picture in a corresponding VOB which includes the information of an address of a first still picture S_VOG_SA and the size of the picture.
 5. A method of playing back information on a storage medium, comprising the steps of: reading on the storage medium control information indicating information about still picture information; and accessing at least one picture object containing still picture information using the control information which has been read, wherein the control information includes: a still picture AV file information table S_AVFIT which includes still picture AV file information S_AVFI, the still picture AV file information S_AVFI including: a section of general information S_AVFI_GI for picture object management; at least one search pointer S_VOGI_SRP#i which describes a start address of video object group information S_VOGI; and at least one video object information for picture object S_VOGI#i, the at least one video object information for picture objects S_VOGI#i including: still picture VOB group general information S_VOGI_GI containing information of a still picture VOB group, and a still picture VOB entry S_VOB_ENT# which contains information of how to access objects including pictures, the at least one video object information for picture objects S_VOGI#i including information of an address of a first still picture S_VOG_SA and a size of a picture, said still picture VOB entry S_VOB_ENT# including temporary erase information TE which indicates whether a still picture VOB corresponding to said still picture VOB entry S_VOB_ENT# is in a temporarily erased state.
 6. A method according to claim 5, wherein the still picture VOB group general information S_VOGI_GI and the still picture VOB entry S_VOB_ENT# are included in information of a still picture in a corresponding VOB which includes the information of an address of a first still picture S_VOG_SA and the size of the picture.
 7. A system for playing back information on a storage medium, comprising: means for reading on the storage medium control information indicating information about still picture information; and means for accessing at least one picture object containing still picture information using the control information which has been read, wherein the control information includes: a still picture AV file information table S_AVFIT which includes still picture AV file information S_AVFI, the still picture AV file information S_AVFI including: a section of general information S_AVFI_GI for picture object management; at least one search pointer S_VOGI_SRP#i which describes a start address of video object group information S_VOGI; and at least one video object information for picture object S_VOGI#i, the at least one video object information for picture objects S_VOGI#i including: still picture VOB group general information S_VOGI_GI containing information of a still picture VOB group, and a still picture VOB entry S_VOB_ENT# which contains information of how to access objects including pictures, the at least one video object information for picture objects S_VOGI#I including information of an address of a first still picture S_VOG_SA and a size of a picture, said still picture VOB entry S_VOB_ENT# including temporary erase information TE which indicates whether a still picture VOB corresponding to said still picture VOB entry S_VOB_ENT# is in a temporarily erased state.
 8. A system according to claim 7, wherein the still picture VOB group general information S_VOGI_GI and the still picture VOB entry S_VOB_ENT# are included in information of a still picture in a corresponding VOB which includes the information of an address of a first still picture S_VOG_SA and the size of the picture. 